Bibliography.bib

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  title = {Ultrafast optical manipulation of magnetic order},
  author = {Kirilyuk, Andrei and Kimel, Alexey V. and Rasing, Theo},
  journal = {Rev. Mod. Phys.},
  volume = {82},
  issue = {3},
  pages = {2731--2784},
  numpages = {0},
  year = {2010},
  publisher = {American Physical Society},
  doi = {10.1103/RevModPhys.82.2731},
  url = {https://link.aps.org/doi/10.1103/RevModPhys.82.2731}
}

@article{PhysRev.82.565,
  title = {Theory of Antiferromagnetic Resonance},
  author = {Kittel, C.},
  journal = {Phys. Rev.},
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  issue = {4},
  pages = {565--565},
  numpages = {0},
  year = {1951},
  publisher = {American Physical Society},
  doi = {10.1103/PhysRev.82.565},
  url = {https://link.aps.org/doi/10.1103/PhysRev.82.565}
}

@article{PhysRev.85.329,
  title = {Theory of Antiferromagnetic Resonance},
  author = {Keffer, F. and Kittel, C.},
  journal = {Phys. Rev.},
  volume = {85},
  issue = {2},
  pages = {329--337},
  numpages = {0},
  year = {1952},
  publisher = {American Physical Society},
  doi = {10.1103/PhysRev.85.329},
  url = {https://link.aps.org/doi/10.1103/PhysRev.85.329}
}

@article{zener1951interaction,
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  journal={Phys. Rev.},
  volume={81},
  number={3},
  pages={440},
  year={1951},
  publisher={APS}
}

@article{kasuya1956theory,
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  journal={Prog. Theor. Phys.},
  volume={16},
  number={1},
  pages={45--57},
  year={1956},
  publisher={Oxford University Press}
}
@article{yosida1957magnetic,
  title={Magnetic properties of Cu-Mn alloys},
  author={Yosida, Kei},
  journal={Phys. Rev.},
  volume={106},
  number={5},
  pages={893},
  year={1957},
  publisher={APS}
}
@article{10.1143/PTP.32.37,
    author = {Kondo, Jun},
    title = "{Resistance Minimum in Dilute Magnetic Alloys}",
    journal = {Progress of Theoretical Physics},
    volume = {32},
    number = {1},
    pages = {37-49},
    year = {1964},
    month = {07},
    abstract = "{Based on the $s$--$d$ interaction model for dilute magnetic alloys we have calculated the scattering probability of the conduction electrons to the second Born approximation. Because of the dynamical character of the localized spin system, the Pauli principle should be taken into account in the intermediate states of the second order terms. Thus the effect of the Fermi sphere is involved in the scattering probability and gives rise to a singular term in the resistivity which involves c log T as a factor, where c is the concentration of impurity atoms. When combined with the lattice resistivity, this gives rise to a resistance minimum, provided the $s$--$d$ exchange integral J is negative. The temperature at which the minimum ccurs is proportional to c1/5 and the depth of the minimum to c, as is observed. The predicted log T dependence is tested with available experiments and is confirmed. The value of J to have fit with experiments is about -0.2 ev, which is of reasonable magnitude. Our conclusion is that J should be negative in alloys which show a resistance minimum. It is argued that the resistance minimum is a result of the sharp Fermi surface.}",
    issn = {0033-068X},
    doi = {10.1143/PTP.32.37},
    url = {https://doi.org/10.1143/PTP.32.37},
    eprint = {https://academic.oup.com/ptp/article-pdf/32/1/37/5193092/32-1-37.pdf},
}


@article{Kubo_1966,
	doi = {10.1088/0034-4885/29/1/306},
	url = {https://doi.org/10.1088%2F0034-4885%2F29%2F1%2F306},
	year = 1966,
	publisher = {{IOP} Publishing},
	volume = {29},
	number = {1},
	pages = {255--284},
	author = {R Kubo},
	title = {The fluctuation-dissipation theorem},
	journal = {Reports on Progress in Physics},
	abstract = {The linear response theory has given a general proof of the fluctuation-dissipation theorem which states that the linear response of a given system to an external perturbation is expressed in terms of fluctuation properties of the system in thermal equilibrium. This theorem may be represented by a stochastic equation describing the fluctuation, which is a generalization of the familiar Langevin equation in the classical theory of Brownian motion. In this generalized equation the friction force becomes retarded or frequency-dependent and the random force is no more white. They are related to each other by a generalized Nyquist theorem which is in fact another expression of the fluctuation-dissipation theorem. This point of view can be applied to a wide class of irreversible process including collective modes in many-particle systems as has already been shown by Mori. As an illustrative example, the density response problem is briefly discussed.}
}
@article{qi_topological_2008,
 author = {Qi, Xiao-Liang and Hughes, Taylor L. and Zhang, Shou-Cheng},
 title = {Topological field theory of time-reversal invariant insulators},
 volume = {78},
 url = {https://doi.org/10.1103/physrevb.78.195424},
 doi = {10.1103/physrevb.78.195424},
 abstract = {We show that the fundamental time-reversal invariant (TRI) insulator exists in 4+1 dimensions, where the effective-field theory is described by the (4+1)-dimensional Chern-Simons theory and the topological properties of the electronic structure are classified by the second Chern number. These topological properties are the natural generalizations of the time reversal-breaking quantum Hall insulator in 2+1 dimensions. The TRI quantum spin Hall insulator in 2+1 dimensions and the topological insulator in 3+1 dimensions can be obtained as descendants from the fundamental TRI insulator in 4+1 dimensions through a dimensional reduction procedure. The effective topological field theory and the Z2 topological classification for the TRI insulators in 2+1 and 3+1 dimensions are naturally obtained from this procedure. All physically measurable topological response functions of the TRI insulators are completely described by the effective topological field theory. Our effective topological field theory predicts a number of measurable phenomena, the most striking of which is the topological magnetoelectric effect, where an electric field generates a topological contribution to the magnetization in the same direction, with a universal constant of proportionality quantized in odd multiples of the fine-structure constant $\alpha =e^2/\hbar c$. Finally, we present a general classification of all topological insulators in various dimensions and describe them in terms of a unified topological Chern-Simons field theory in phase space.},
 number = {19},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = nov,
 year = {2008},
 pages = {195424},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/U523P7V9/PhysRevB.78.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{garate_inverse_2010,
 author = {Garate, Ion and Franz, M.},
 title = {Inverse Spin-Galvanic Effect in the Interface between a Topological Insulator and a Ferromagnet},
 volume = {104},
 url = {https://doi.org/10.1103/physrevlett.104.146802},
 doi = {10.1103/physrevlett.104.146802},
 abstract = {When a ferromagnet is deposited on the surface of a topological insulator the topologically protected surface state develops a gap and becomes a two-dimensional quantum Hall liquid. We demonstrate that the Hall current in such a liquid, induced by an external electric field, can have a dramatic effect on the magnetization dynamics of the ferromagnet by changing the effective anisotropy field. This change is dissipationless and may be substantial even in weakly spin-orbit coupled ferromagnets. We study the possibility of dissipationless current-induced magnetization reversal in monolayer-thin, insulating ferromagnets with a soft perpendicular anisotropy and discuss possible applications of this effect.},
 number = {14},
 urldate = {2018-02-01},
 journal = {Phys. Rev. Lett.},
 month = apr,
 year = {2010},
 pages = {146802},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/A7JFY4TC/PhysRevLett.104.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@misc{noauthor_phys._nodate,
 title = {Phys. {{Rev}.} {B} 81, {241410({R})} (2010) - {Theoretical} study of the dynamics of magnetization on the topological surface},
 url = {https://journals.aps.org/prb/abstract/10.1103/PhysRevB.81.241410},
 urldate = {2018-02-01},
 file = {Phys. Rev. B 81, 241410(R) (2010) - Theoretical study of the dynamics of magnetization on the topological surface:/home/rsokolewicz/Zotero/storage/YF9ENYX3/PhysRevB.81.html:text/html},
}

@article{fujimoto_transport_2014,
 author = {Fujimoto, Junji and Kohno, Hiroshi},
 title = {Transport properties of {Dirac} ferromagnet},
 volume = {90},
 url = {https://doi.org/10.1103/physrevb.90.214418},
 doi = {10.1103/physrevb.90.214418},
 abstract = {We propose a model ferromagnet based on the Dirac Hamiltonian in three spatial dimensions, and study its transport properties which include anisotropic magnetoresistance (AMR) and anomalous Hall (AH) effect. This relativistic extension allows two kinds of ferromagnetic order parameters, denoted by M and S, which are distinguished by the relative sign between the positive- and negative-energy states (at zero momentum) and become degenerate in the nonrelativistic limit. Because of the relativistic coupling between the spin and the orbital motion, both M and S induce anisotropic deformations of the energy dispersion (and the Fermi surfaces) but in mutually opposite ways. The AMR is determined primarily by the anisotropy of the Fermi surface (group velocity), and secondarily by the anisotropy of the damping; the latter becomes important for M=$\pm$S, where the Fermi surfaces are isotropic. Even when the chemical potential lies in the gap, the AH conductivity is found to take a finite nonquantized value $\sigma \_{ij}=$-$(\alpha /3\pi ^2\hbar )\epsilon \_{ijk}S\_k$, where $\alpha$ is the (effective) fine structure constant. This offers an example of Hall insulator in three spatial dimensions.},
 number = {21},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = dec,
 year = {2014},
 pages = {214418},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/WHEMC4FN/PhysRevB.90.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{okuma_unconventional_2016,
 author = {Okuma, Nobuyuki and Ogata, Masao},
 title = {Unconventional spin Hall effect and axial current generation in a {Dirac} semimetal},
 volume = {93},
 url = {https://doi.org/10.1103/physrevb.93.140205},
 doi = {10.1103/physrevb.93.140205},
 abstract = {We investigate electrical transport in a three-dimensional massless Dirac fermion model that describes a Dirac semimetal state realized in topological materials. We derive a set of interdependent diffusion equations with eight local degrees of freedom, including the electric charge density and the spin density, that respond to an external electric field. By solving the diffusion equations for a system with a boundary, we demonstrate that a spin Hall effect with spin accumulation occurs even though the conventional spin current operator is zero. The Noether current associated with chiral symmetry, known as the axial current, is also discussed. We demonstrate that the axial current flows near the boundary and that it is perpendicular to the electric current.},
 number = {14},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = apr,
 year = {2016},
 pages = {140205},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/39DMWHVQ/PhysRevB.93.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{yokoyama_current-induced_2011,
 author = {Yokoyama, Takehito},
 title = {Current-induced magnetization reversal on the surface of a topological insulator},
 volume = {84},
 url = {https://doi.org/10.1103/physrevb.84.113407},
 doi = {10.1103/physrevb.84.113407},
 abstract = {We study the dynamics of magnetization coupled to the surface Dirac fermions of a three-dimensional topological insulator. By solving the Landau-Lifshitz-Gilbert equation in the presence of a charge current, we find current-induced magnetization dynamics and discuss the possibility of magnetization reversal. The torque from the current injection depends on the transmission probability through the ferromagnet and shows nontrivial dependence on the exchange coupling. The magnetization dynamics is a direct manifestation of the inverse spin-galvanic effect and hence another ferromagnet is unnecessary to induce spin-transfer torque in contrast to the conventional setup.},
 number = {11},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = sep,
 year = {2011},
 pages = {113407},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/5KTAEYX5/PhysRevB.84.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{nomura_electric_2010,
 author = {Nomura, Kentaro and Nagaosa, Naoto},
 title = {Electric charging of magnetic textures on the surface of a topological insulator},
 volume = {82},
 url = {https://doi.org/10.1103/physrevb.82.161401},
 doi = {10.1103/physrevb.82.161401},
 abstract = {A three-dimensional topological insulator manifests gapless surface modes, described by two-dimensional Dirac equation. We study magnetic textures, such as domain walls and vortices, in a ferromagnetic thin film deposited on a three-dimensional topological insulator. It is shown that these textures can be electrically charged, ascribed to the proximity effect with the Dirac surface states. We derive a general relation between the electric and the magnetic charges. As a physical consequence, we discuss domain-wall motion driven by an applied electric field, which promises magnetic devices with high thermal efficiency.},
 number = {16},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = oct,
 year = {2010},
 pages = {161401},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/6LVJSRNY/PhysRevB.82.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@misc{noauthor_phys._nodate-1,
 title = {Phys. {{Rev}.} {{Lett}.} 108, 187201 (2012) - {Thin}-{Film} {Magnetization} {Dynamics} on the {Surface} of a {Topological} {Insulator}},
 url = {https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.108.187201},
 urldate = {2018-02-01},
 file = {Phys. Rev. Lett. 108, 187201 (2012) - Thin-Film Magnetization Dynamics on the Surface of a Topological Insulator:/home/rsokolewicz/Zotero/storage/3HF4RJ3D/PhysRevLett.108.html:text/html},
}

@article{linder_improved_2014,
 author = {Linder, Jacob},
 title = {Improved domain-wall dynamics and magnonic torques using topological insulators},
 volume = {90},
 url = {https://doi.org/10.1103/physrevb.90.041412},
 doi = {10.1103/physrevb.90.041412},
 abstract = {We investigate the magnetization dynamics that arises when a thin-film ferromagnet is deposited on a topological insulator (TI), focusing in particular on domain-wall motion via current and the possibility of a spin-wave torque acting on the magnetization. We show analytically that the coupling between the magnetic domain wall and the TI removes the degeneracy of the wall profile with respect to its chirality and topological charge. Moreover, we find that the threshold for Walker breakdown of domain-wall motion is substantially increased and determined by the interaction with the TI, allowing for higher attainable wall velocities than in the conventional case where the hard-axis anisotropy determines the Walker threshold. Finally, we show that the allowed modes of spin-wave excitations and the ensuing magnetization dynamics in the presence of a TI coupling enable a magnonic torque acting even on homogeneous magnetization textures. Our results indicate that the TI-ferromagnet interaction has a similar effect on the magnetization dynamics as an intrinsic Dzyaloshinskii-Moriya interaction in ferromagnets.},
 number = {4},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = jul,
 year = {2014},
 pages = {041412},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/9LMH86KR/PhysRevB.90.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@footnote{Note1,
 key = {Note1},
}

@article{tserkovnyak_spin_2015,
 author = {Tserkovnyak, Yaroslav and Pesin, D.A. and Loss, Daniel},
 title = {Spin and orbital magnetic response on the surface of a topological insulator},
 volume = {91},
 url = {https://doi.org/10.1103/physrevb.91.041121},
 doi = {10.1103/physrevb.91.041121},
 abstract = {Coupling of the spin and orbital degrees of freedom on the surface of a strong three-dimensional insulator, on the one hand, and textured magnetic configuration in an adjacent ferromagnetic film, on the other, is studied using a combination of transport and thermodynamic considerations. Expressing exchange coupling between the localized magnetic moments and Dirac electrons in terms of the electrons' out-of-plane orbital and spin magnetizations, we relate the thermodynamic properties of a general ferromagnetic spin texture to the physics in the zeroth Landau level. Persistent currents carried by Dirac electrons endow the magnetic texture with a Dzyaloshinski-Moriya interaction, which exhibits a universal scaling form as a function of electron temperature, chemical potential, and the time-reversal symmetry breaking gap. In addition, the orbital motion of electrons establishes a direct magnetoelectric coupling between the unscreened electric field and local magnetic order, which furnishes complex long-ranged interactions within the magnetic film.},
 number = {4},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = jan,
 year = {2015},
 pages = {041121},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/EWFHGTZL/PhysRevB.91.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{burkov_spin_2010-1,
 author = {Burkov, A.A. and Hawthorn, D.G.},
 title = {Spin and Charge Transport on the Surface of a Topological Insulator},
 volume = {105},
 url = {https://doi.org/10.1103/physrevlett.105.066802},
 doi = {10.1103/physrevlett.105.066802},
 abstract = {We derive diffusion equations, which describe spin-charge coupled transport on the helical metal surface of a three-dimensional topological insulator. The main feature of these equations is a large magnitude of the spin-charge coupling, which leads to interesting and observable effects. In particular, we predict a new magnetoresistance effect, which manifests in a non-Ohmic correction to a voltage drop between a ferromagnetic spin-polarized electrode and a nonmagnetic electrode, placed on top of the helical metal. This correction is proportional to the cross product of the spin polarization of the ferromagnetic electrode and the charge current between the two electrodes. We also demonstrate tunability of this effect by applying a gate voltage, which makes it possible to operate the proposed device as a transistor.},
 number = {6},
 urldate = {2018-02-01},
 journal = {Phys. Rev. Lett.},
 month = aug,
 year = {2010},
 pages = {066802},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/HVT4C4J9/PhysRevLett.105.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{ueda_topological_2012,
 author = {Ueda, Hiroaki T. and Takeuchi, Akihito and Tatara, Gen and Yokoyama, Takehito},
 title = {Topological charge pumping effect by the magnetization dynamics on the surface of three-dimensional topological insulators},
 volume = {85},
 url = {https://doi.org/10.1103/physrevb.85.115110},
 doi = {10.1103/physrevb.85.115110},
 abstract = {We discuss a current dynamics on the surface of a three-dimensional topological insulator induced by magnetization precession of an attached ferromagnet. It is found that the magnetization dynamics generates a direct charge current when the precession axis is within the surface plane. This rectification effect is due to a quantum anomaly and is topologically protected. The robustness of the rectification effect against first-varying exchange field and impurities is confirmed by explicit calculation.},
 number = {11},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = mar,
 year = {2012},
 pages = {115110},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/NFB6ZSIH/PhysRevB.85.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{liu_reading_2013,
 author = {Liu, Xin and Sinova, Jairo},
 title = {Reading Charge Transport from the Spin Dynamics on the Surface of a Topological Insulator},
 volume = {111},
 url = {https://doi.org/10.1103/physrevlett.111.166801},
 doi = {10.1103/physrevlett.111.166801},
 abstract = {Resolving the conductance of the topological surface states (TSSs) from the bulk contribution has been a great challenge for studying the transport properties of topological insulators. By developing a nonperturbative diffusion equation that describes fully the spin-charge dynamics in the strong spin-orbit coupling regime, we present a proposal to read the charge transport information of TSSs from its spin dynamics which can be isolated from the bulk contribution by the time-resolved second harmonic generation pump-probe measurement. We demonstrate the qualitatively different Dyaknov-Perel spin relaxation behavior between the TSSs and the two-dimensional spin-orbit coupling electron gas. The decay time of both in-plane and out-of-plane spin polarization is naturally proved to be identical to the charge transport time. The out-of-plane spin dynamics is shown to be in the experimentally reachable regime of the femtosecond pump-probe spectroscopy and thereby we suggest experiments to detect the charge transport properties of the TSSs from their unique spin dynamics.},
 number = {16},
 urldate = {2018-02-01},
 journal = {Phys. Rev. Lett.},
 month = oct,
 year = {2013},
 pages = {166801},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/ZRM45ZGR/PhysRevLett.111.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{chang_nonequilibrium_2015,
 author = {Chang, Po-Hao and Markussen, Troels and Smidstrup, Søren and Stokbro, Kurt and Nikolić, Branislav K.},
 title = {Nonequilibrium spin texture within a thin layer below the surface of current-carrying topological insulator Bi2Se3: A first-principles quantum transport study},
 volume = {92},
 
 url = {https://doi.org/10.1103/physrevb.92.201406},
 doi = {10.1103/physrevb.92.201406},
 abstract = {We predict that unpolarized charge current injected into a ballistic thin film of prototypical topological insulator (TI) Bi2Se3 will generate a noncollinear spin texture S(r) on its surface. Furthermore, the nonequilibrium spin texture will extend into an $\simeq 2$-nm-thick layer below the TI surfaces due to penetration of evanescent wave functions from the metallic surfaces into the bulk of TI. Averaging S(r) over a few angstroms along the longitudinal direction defined by the current flow reveals a large component pointing in the transverse direction. In addition, we find an order of magnitude smaller out-of-plane component when the direction of injected current with respect to Bi and Se atoms probes the largest hexagonal warping of the Dirac-cone dispersion on the TI surface. Our analysis is based on an extension of the nonequilibrium Green's functions combined with density functional theory (NEGF+DFT) to situations involving noncollinear spins and spin-orbit coupling. We also demonstrate how DFT calculations with a properly optimized local orbital basis set can precisely match putatively more accurate calculations with a plane-wave basis set for the supercell of Bi2Se3.},
 number = {20},
 urldate = {2018-02-01},
 journal = {Phys. Rev. B},
 month = nov,
 year = {2015},
 pages = {201406},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/LPMBR8Y4/PhysRevB.92.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{ivan,
 author = {Ado, I.A. and Dmitriev, I.A. and Ostrovsky, P.M. and Titov, M.},
 title = {Anomalous Hall effect with massive {Dirac} fermions},
 volume = {111},
 issn = {0295-5075, 1286-4854},
 doi = {10.1209/0295-5075/111/37004},
 timestamp = {2017-07-19T12:38:30Z},
 number = {3},
 urldate = {2017-07-19},
 url = {https://doi.org/10.1209/0295-5075/111/37004},
 journal = {EPL},
 month = aug,
 year = {2015},
 pages = {37004},
 file = {untitled - pdf:/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/FVMU8V4T/pdf.pdf:application/pdf},
 source = {Crossref},
 publisher = {IOP Publishing},
}

@article{awschalom2009trend,
 author = {Awschalom, David and Samarth, Nitin},
 title = {Spintronics without magnetism},
 journal = {Physics},
 volume = {2},
 pages = {50},
 year = {2009},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physics.2.50},
 source = {Crossref},
 url = {https://doi.org/10.1103/physics.2.50},
 issn = {1943-2879},
 month = jun,
}

@article{miron_perpendicular_2011,
 author = {Miron, Ioan Mihai and Garello, Kevin and Gaudin, Gilles and Zermatten, Pierre-Jean and Costache, Marius V. and Auffret, Stéphane and Bandiera, Sébastien and Rodmacq, Bernard and Schuhl, Alain and Gambardella, Pietro},
 title = {Perpendicular switching of a single ferromagnetic layer induced by in-plane current injection},
 volume = {476},
 number = {7359},
 journal = {Nature},
 year = {2011},
 pages = {189-193},
 annote = {SOT experiment},
 doi = {10.1038/nature10309},
 source = {Crossref},
 url = {https://doi.org/10.1038/nature10309},
 publisher = {Springer Science and Business Media LLC},
 issn = {0028-0836, 1476-4687},
 month = aug,
}

@article{mellnik_spin-transfer_2014,
 author = {Mellnik, A.R. and Lee, J.S. and Richardella, A. and Grab, J.L. and Mintun, P.J. and Fischer, M.H. and Vaezi, A. and Manchon, A. and Kim, E.-A. and Samarth, N. and Ralph, D.C.},
 title = {Spin-transfer torque generated by a topological insulator},
 volume = {511},
 issn = {0028-0836, 1476-4687},
 doi = {10.1038/nature13534},
 timestamp = {2017-06-15T12:45:24Z},
 number = {7510},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1038/nature13534},
 journal = {Nature},
 month = jul,
 year = {2014},
 pages = {449-451},
 file = {Spin-transfer torque generated by a topological insulator - nature13534.pdf:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/JD7WZJBV/nature13534.pdf:application/pdf},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{hsieh_topological_2008,
 author = {Hsieh, D. and Qian, D. and Wray, L. and Xia, Y. and Hor, Y.S. and Cava, R.J. and Hasan, M.Z.},
 title = {A topological {Dirac} insulator in a quantum spin Hall phase},
 volume = {452},
 copyright = {\copyright\ 2008 Nature Publishing Group},
 issn = {0028-0836, 1476-4687},
 url = {https://doi.org/10.1038/nature06843},
 doi = {10.1038/nature06843},
 abstract = {When electrons are subject to a large external magnetic field, the conventional charge quantum Hall effect dictates that an electronic excitation gap is generated in the sample bulk, but metallic conduction is permitted at the boundary. Recent theoretical models suggest that certain bulk insulators with large spin--orbit interactions may also naturally support conducting topological boundary states in the quantum limit, which opens up the possibility for studying unusual quantum Hall-like phenomena in zero external magnetic fields. Bulk Bi1-xSbx single crystals are predicted to be prime candidates for one such unusual Hall phase of matter known as the topological insulator. The hallmark of a topological insulator is the existence of metallic surface states that are higher-dimensional analogues of the edge states that characterize a quantum spin Hall insulator. In addition to its interesting boundary states, the bulk of Bi1-xSbx is predicted to exhibit three-dimensional Dirac particles, another topic of heightened current interest following the new findings in two-dimensional graphene and charge quantum Hall fractionalization observed in pure bismuth. However, despite numerous transport and magnetic measurements on the Bi1-xSbx family since the 1960s, no direct evidence of either topological Hall states or bulk Dirac particles has been found. Here, using incident-photon-energy-modulated angle-resolved photoemission spectroscopy (IPEM-ARPES), we report the direct observation of massive Dirac particles in the bulk of Bi0.9Sb0.1, locate the Kramers points at the sample's boundary and provide a comprehensive mapping of the Dirac insulator's gapless surface electron bands. These findings taken together suggest that the observed surface state on the boundary of the bulk insulator is a realization of the 'topological metal'. They also suggest that this material has potential application in developing next-generation quantum computing devices that may incorporate 'light-like' bulk carriers and spin-textured surface currents.},
 
 number = {7190},
 urldate = {2017-10-16},
 journal = {Nature},
 month = apr,
 year = {2008},
 pages = {970-974},
 file = {Full Text PDF:/home/rsokolewicz/Zotero/storage/CGTPREYJ/Hsieh et al. - 2008 - A topological Dirac insulator in a quantum spin Ha.pdf:application/pdf;Snapshot:/home/rsokolewicz/Zotero/storage/KAENYYM7/nature06843.html:text/html},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{fan_magnetization_2014,
 author = {Fan, Yabin and Upadhyaya, Pramey and Kou, Xufeng and Lang, Murong and Takei, So and Wang, Zhenxing and Tang, Jianshi and He, Liang and Chang, Li-Te and Montazeri, Mohammad and Yu, Guoqiang and Jiang, Wanjun and Nie, Tianxiao and Schwartz, Robert N. and Tserkovnyak, Yaroslav and Wang, Kang L.},
 title = {Magnetization switching through giant spin--orbit torque in a magnetically doped topological insulator heterostructure},
 volume = {13},
 issn = {1476-1122, 1476-4660},
 
 doi = {10.1038/nmat3973},
 timestamp = {2017-06-15T12:45:39Z},
 number = {7},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1038/nmat3973},
 journal = {Nat. Mater.},
 month = apr,
 year = {2014},
 pages = {699-704},
 file = {Magnetization switching through giant spin--orbit torque in a magnetically doped topological insulator heterostructure - nmat3973.pdf:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/DIBVN842/nmat3973.pdf:application/pdf},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{rodriguez-vega_giant_2016,
  title = {Giant Edelstein effect in topological-insulator--graphene heterostructures},
  author = {Rodriguez-Vega, M. and Schwiete, G. and Sinova, J. and Rossi, E.},
  journal = {Phys. Rev. B},
  volume = {96},
  issue = {23},
  pages = {235419},
  numpages = {8},
  year = {2017},
  publisher = {American Physical Society},
  doi = {10.1103/PhysRevB.96.235419},
  url = {https://link.aps.org/doi/10.1103/PhysRevB.96.235419}
}


@article{ryu_chiral_2013,
 author = {Ryu, Kwang-Su and Thomas, Luc and Yang, See-Hun and Parkin, Stuart},
 title = {Chiral spin torque at magnetic domain walls},
 volume = {8},
 issn = {1748-3387, 1748-3395},
 doi = {10.1038/nnano.2013.102},
 timestamp = {2017-07-10T09:48:04Z},
 number = {7},
 urldate = {2017-07-10},
 url = {https://doi.org/10.1038/nnano.2013.102},
 journal = {Nat. Nanotechnol.},
 month = jun,
 year = {2013},
 pages = {527-533},
 file = {Chiral spin torque at magnetic domain walls - nnano.2013.102.pdf:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/N8GT42VD/nnano.2013.102.pdf:application/pdf},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{kurebayashi_microscopic_2017,
 author = {Kurebayashi, Daichi and Nomura, Kentaro},
 title = {Microscopic Theory of Electrically Induced Spin Torques in Magnetic {{Weyl}} Semimetals},
 abstract = {We theoretically study electrical responses of magnetization in Weyl semimetals. The Weyl semimetal is a new class of topological semimetals, possessing hedgehog type spin textures in momentum space. Because of this peculiar spin texture, an interplay of electron transport and spin dynamics might provide new method to electrical control of magnetization. In this paper, we consider the magnetically doped Weyl semimetals, and systematically study current- and charge-induced spin torque exerted on the local magnetization in three-dimensional Dirac-Weyl metals. We determine all current-induced spin torques including spin-orbit torque, spin-transfer torque, and the so-called \$\beta\$-term, up to first order with respect to spatial and temporal derivation and electrical currents. We find that spin-transfer torque and \$\beta\$-term are absent while spin-orbit torque is proportional to the axial current density. We also calculate the charge-induced spin torque microscopically. We find the charge-induced spin torque originates from the chiral anomaly due to the correspondence between spin operators and axial current operators in our model.},
 timestamp = {2017-06-15T12:37:16Z},
 eprinttype = {arxiv},
 eprint = {1702.04918},
 primaryclass = {cond-mat},
 urldate = {2017-06-15},
 url = {http://arxiv.org/abs/1702.04918},
 journal = {arXiv:1702.04918 [cond-mat]},
 month = feb,
 year = {2017},
 keywords = {Condensed Matter - Mesoscale and Nanoscale Physics},
 file = {arXiv\:1702.04918 PDF:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/VTQN4CXT/Kurebayashi and Nomura - 2017 - Microscopic theory of electrically induced spin to.pdf:application/pdf;arXiv.org Snapshot:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/BPP83HR2/1702.html:text/html},
}

@article{taguchi_spin-charge_2015,
 author = {Taguchi, Katsuhisa and Shintani, Kunitaka and Tanaka, Yukio},
 title = {Spin-charge transport driven by magnetization dynamics on the disordered surface of doped topological insulators},
 volume = {92},
 issn = {1098-0121, 1550-235X},
 url = {https://doi.org/10.1103/physrevb.92.035425},
 doi = {10.1103/physrevb.92.035425},
 pages = {035425},
 number = {3},
 urldate = {2017-09-29},
 journal = {Phys. Rev. B},
 month = jul,
 year = {2015},
 file = {PhysRevB.92.pdf:/home/rsokolewicz/Zotero/storage/UULYXCIG/PhysRevB.92.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{yokoyama_transverse_2011,
 author = {Yokoyama, Takehito and Murakami, Shuichi},
 title = {Transverse magnetic heat transport on the surface of a topological insulator},
 volume = {83},
 issn = {1098-0121, 1550-235X},
 url = {https://doi.org/10.1103/physrevb.83.161407},
 doi = {10.1103/physrevb.83.161407},
 
 number = {16},
 urldate = {2017-10-09},
 journal = {Phys. Rev. B},
 month = apr,
 year = {2011},
 file = {PhysRevB.83.pdf:/home/rsokolewicz/Zotero/storage/VV2W3KJL/PhysRevB.83.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{shintani_spin_2016,
 author = {Shintani, Kunitaka and Taguchi, Katsuhisa and Tanaka, Yukio and Kawaguchi, Yuki},
 title = {Spin and charge transport induced by a twisted light beam on the surface of a topological insulator},
 volume = {93},
 url = {https://doi.org/10.1103/physrevb.93.195415},
 doi = {10.1103/physrevb.93.195415},
 abstract = {We theoretically study spin and charge transport induced by a twisted light beam irradiated on a disordered surface of a doped three-dimensional topological insulator (TI). We find that various types of spin vortices are imprinted on the surface of the TI depending on the spin and orbital angular momentum of the incident light. The key mechanism for the appearance of the unconventional spin structure is the spin-momentum locking in the surface state of the TI. Besides, the diffusive transport of electrons under an inhomogeneous electric field causes a gradient of the charge density, which then induces nonlocal charge current and spin density as well as the spin current. We discuss the relation between these quantities within the linear response to the applied electric field using the Keldysh-Green's function method.},
 number = {19},
 urldate = {2017-10-25},
 journal = {Phys. Rev. B},
 month = may,
 year = {2016},
 pages = {195415},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/PPTWEDIG/PhysRevB.93.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{fu_probing_2009,
 author = {Fu, Liang and Kane, C.L.},
 title = {Probing Neutral Majorana Fermion Edge Modes with Charge Transport},
 volume = {102},
 url = {https://doi.org/10.1103/physrevlett.102.216403},
 doi = {10.1103/physrevlett.102.216403},
 abstract = {We propose two experiments to probe the Majorana fermion edge states that occur at a junction between a superconductor and a magnet deposited on the surface of a topological insulator. Combining two Majorana fermions into a single Dirac fermion on a magnetic domain wall allows the neutral Majorana fermions to be probed with charge transport. We will discuss a novel interferometer for Majorana fermions, which probes their Z2 phase. This setup also allows the transmission of neutral Majorana fermions through a point contact to be measured. We introduce a point contact formed by a superconducting junction and show that its transmission can be controlled by the phase difference across the junction. We discuss the feasibility of these experiments using the recently discovered topological insulator Bi2Se3.},
 number = {21},
 urldate = {2017-10-16},
 journal = {Phys. Rev. Lett.},
 month = may,
 year = {2009},
 pages = {216403},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/6PT68GBI/PhysRevLett.102.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{roy_$z_2$_2009,
 author = {Roy, Rahul},
 title = {Z2classification of quantum spin Hall systems: {An} approach using time-reversal invariance},
 volume = {79},
 url = {https://doi.org/10.1103/physrevb.79.195321},
 doi = {10.1103/physrevb.79.195321},
 abstract = {We study the phases of Bloch insulators with time-reversal symmetry on the basis of the homotopy of the ground-state wave functions in momentum space and find that there are two topological classes characterized by a Z2 invariant. The results are in agreement with a recent study based on counting the zeroes of a certain Pfaffian function related to the ground-state wave function. It is shown that there is a link between the formulation of the topological invariant presented here and the number of robust edge states. A formula is also provided which greatly simplifies the computation of the invariant in a large number of cases. The present study provides guidance for the search of systems which belong to the nontrivial topological class and also establishes a link between the quantum spin Hall effect and the integer quantum Hall effect.},
 number = {19},
 urldate = {2017-10-16},
 journal = {Phys. Rev. B},
 month = may,
 year = {2009},
 pages = {195321},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/4I72ZQKR/PhysRevB.79.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{moore_topological_2007,
 author = {Moore, J.E. and Balents, L.},
 title = {Topological invariants of time-reversal-invariant band structures},
 volume = {75},
 url = {https://doi.org/10.1103/physrevb.75.121306},
 doi = {10.1103/physrevb.75.121306},
 abstract = {The topological invariants of a time-reversal-invariant band structure in two dimensions are multiple copies of the Z2 invariant found by Kane and Mele. Such invariants protect the ``topological insulator'' phase and give rise to a spin Hall effect carried by edge states. Each pair of bands related by time reversal is described by one Z2 invariant, up to one less than half the dimension of the Bloch Hamiltonians. In three dimensions, there are four such invariants per band pair. The Z2 invariants of a crystal determine the transitions between ordinary and topological insulators as its bands are occupied by electrons. We derive these invariants using maps from the Brillouin zone to the space of Bloch Hamiltonians and clarify the connections between Z2 invariants, the integer invariants that underlie the integer quantum Hall effect, and previous invariants of T-invariant Fermi systems.},
 number = {12},
 urldate = {2017-10-16},
 journal = {Phys. Rev. B},
 month = mar,
 year = {2007},
 pages = {121306},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/WXW8HPIU/PhysRevB.75.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{fu_topological_2007,
 author = {Fu, Liang and Kane, C.L. and Mele, E.J.},
 title = {Topological Insulators in Three Dimensions},
 volume = {98},
 url = {https://doi.org/10.1103/physrevlett.98.106803},
 doi = {10.1103/physrevlett.98.106803},
 abstract = {We study three-dimensional generalizations of the quantum spin Hall (QSH) effect. Unlike two dimensions, where a single Z2 topological invariant governs the effect, in three dimensions there are 4 invariants distinguishing 16 phases with two general classes: weak (WTI) and strong (STI) topological insulators. The WTI are like layered 2D QSH states, but are destroyed by disorder. The STI are robust and lead to novel ``topological metal'' surface states. We introduce a tight binding model which realizes the WTI and STI phases, and we discuss its relevance to real materials, including bismuth.},
 number = {10},
 urldate = {2017-10-16},
 journal = {Phys. Rev. Lett.},
 month = mar,
 year = {2007},
 pages = {106803},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/STFGS2TI/PhysRevLett.98.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{roy_topological_2009,
 author = {Roy, Rahul},
 title = {Topological phases and the quantum spin Hall effect in three dimensions},
 volume = {79},
 url = {https://doi.org/10.1103/physrevb.79.195322},
 doi = {10.1103/physrevb.79.195322},
 abstract = {We show the existence of topological phases of Bloch insulators with time-reversal symmetry in three dimensions. These phases are characterized by topological Z2 invariants whose stability is studied using band-touching arguments. Unlike insulators which break time-reveral symmetry, some of these topological phases are intrinsically three dimensional. The number of invariants (four) needed to specify the phase of these insulators also differs from the time-reversal-breaking case. The relation between these phases and the quantum spin Hall effect in three dimensions is investigated.},
 number = {19},
 urldate = {2017-10-16},
 journal = {Phys. Rev. B},
 month = may,
 year = {2009},
 pages = {195322},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/W4RCR4ZI/PhysRevB.79.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{ndiaye_dirac_2017,
 author = {Ndiaye, Papa B. and Akosa, C.A. and Fischer, M.H. and Vaezi, A. and Kim, E.-A. and Manchon, A.},
 title = {{Dirac} spin-orbit torques and charge pumping at the surface of topological insulators},
 volume = {96},
 issn = {2469-9950, 2469-9969},
 url = {https://doi.org/10.1103/physrevb.96.014408},
 doi = {10.1103/physrevb.96.014408},
 pages = {014408},
 number = {1},
 urldate = {2017-08-28},
 journal = {Phys. Rev. B},
 month = jul,
 year = {2017},
 file = {PhysRevB.96.pdf:/home/rsokolewicz/Zotero/storage/FD6VJPRZ/PhysRevB.96.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{chen_current-induced_2017,
 author = {Chen, Ji and Peng, Yingzi and Zhou, Jie},
 title = {Current-induced Rashba spin orbit torque in silicene},
 volume = {432},
 issn = {0304-8853},
 doi = {10.1016/j.jmmm.2017.02.043},
 
 timestamp = {2017-06-15T12:45:41Z},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1016/j.jmmm.2017.02.043},
 journal = {J. Magn. Magn. Mater.},
 month = jun,
 year = {2017},
 pages = {554-558},
 file = {Current-induced Rashba spin orbit torque in silicene - 1-s2.0-S0304885316328311-main.pdf:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/R883TQ77/1-s2.0-S0304885316328311-main.pdf:application/pdf},
 source = {Crossref},
 publisher = {Elsevier BV},
}

@article{soleimani_spin-orbit_2017,
 author = {Soleimani, Maryam and Jalili, Seifollah and Mahfouzi, Farzad and Kioussis, Nicholas},
 title = {Spin-orbit torque-driven magnetization switching in {2D}-topological insulator heterostructure},
 volume = {117},
 issn = {0295-5075, 1286-4854},
 doi = {10.1209/0295-5075/117/37001},
 timestamp = {2017-06-15T12:46:27Z},
 number = {3},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1209/0295-5075/117/37001},
 journal = {EPL},
 month = feb,
 year = {2017},
 pages = {37001},
 file = {untitled - pdf:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/AXV7JCNN/pdf.pdf:application/pdf},
 source = {Crossref},
 publisher = {IOP Publishing},
}

@article{siu_spin_2016,
author = {Siu,Zhuo Bin  and Ho,Cong Son  and Tan,Seng Ghee  and Jalil,Mansoor B. A. },
title = {Spin accumulation in disordered topological insulator ultrathin films},
journal = {Journal of Applied Physics},
volume = {122},
number = {7},
pages = {073903},
year = {2017},
doi = {10.1063/1.4985846},
URL = {https://doi.org/10.1063/1.4985846},
eprint = {https://doi.org/10.1063/1.4985846}
}

@article{sakai_spin_2014,
 author = {Sakai, Akio and Kohno, Hiroshi},
 title = {Spin torques and charge transport on the surface of topological insulator},
 volume = {89},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.89.165307},
 pages = {165307},
 timestamp = {2017-06-15T14:51:56Z},
 number = {16},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1103/physrevb.89.165307},
 journal = {Phys. Rev. B},
 month = apr,
 year = {2014},
 file = {PhysRevB.89.pdf:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/59QCWPJA/PhysRevB.89.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{yokoyama_theoretical_2010,
 author = {Yokoyama, Takehito and Zang, Jiadong and Nagaosa, Naoto},
 title = {Theoretical study of the dynamics of magnetization on the topological surface},
 volume = {81},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.81.241410},
pages = {241410},

 timestamp = {2017-07-10T09:25:12Z},
 number = {24},
 urldate = {2017-07-10},
 url = {https://doi.org/10.1103/physrevb.81.241410},
 journal = {Phys. Rev. B},
 month = jun,
 year = {2010},
 file = {PhysRevB.81.241410:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/JE6E5P7J/PhysRevB.81.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@book{sdmodel,
  title={Magnetism, Johh Wiley and Sons},
  author={Vonsovsky, Sergei Vasilyevich},
  address={New York},
  publisher={J. Wiley},
  year={1974}
}

@article{fischer_spin-torque_2016,
 author = {Fischer, Mark H. and Vaezi, Abolhassan and Manchon, Aurelien and Kim, Eun-Ah},
 title = {Spin-torque generation in topological insulator based heterostructures},
 volume = {93},
 issn = {2469-9950, 2469-9969},
 doi = {10.1103/physrevb.93.125303},
 abstract = {Heterostructures utilizing topological insulators exhibit a remarkable spin-torque efficiency. However, the exact origin of the strong torque, in particular whether it stems from the spin-momentum locking of the topological surface states or rather from spin-Hall physics of the topological-insulator bulk remains unclear. Here, we explore a mechanism of spin-torque generation purely based on the topological surface states. We consider topological-insulator-based bilayers involving ferromagnetic metal (TI/FM) and magnetically doped topological insulators (TI/mdTI), respectively. By ascribing the key theoretical differences between the two setups to location and number of active surface states, we describe both setups within the same framework of spin diffusion of the non-equilibrium spin density of the topological surface states. For the TI/FM bilayer, we find large spin-torque efficiencies of roughly equal magnitude for both in-plane and out-of-plane spin torques. For the TI/mdTI bilayer, we elucidate the dominance of the spin-transfer-like torque. However, we cannot explain the orders of magnitude enhancement reported. Nevertheless, our model gives an intuitive picture of spin-torque generation in topological-insulator-based bilayers and provides theoretical constraints on spin-torque generation due to topological surface states.},
 timestamp = {2017-07-10T14:26:06Z},
 number = {12},
 urldate = {2017-07-10},
 url = {https://doi.org/10.1103/physrevb.93.125303},
 journal = {Phys. Rev. B},
 month = mar,
 year = {2016},
   pages = {125303},

 keywords = {Condensed Matter - Mesoscale and Nanoscale Physics},
 file = {arXiv\:1305.1328 PDF:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/D4VQ9ADD/Fischer et al. - 2016 - Spin-Torque Generation in Topological-Insulator-Ba.pdf:application/pdf;arXiv.org Snapshot:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/UBWD74QA/1305.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{pesin_spintronics_2012-1,
 author = {Pesin, Dmytro and MacDonald, Allan H.},
 title = {Spintronics and pseudospintronics in graphene and topological insulators},
 volume = {11},
 issn = {1476-1122, 1476-4660},
 doi = {10.1038/nmat3305},
 timestamp = {2017-07-10T14:26:24Z},
 number = {5},
 urldate = {2017-07-10},
 url = {https://doi.org/10.1038/nmat3305},
 journal = {Nat. Mater.},
 month = apr,
 year = {2012},
 pages = {409-416},
 file = {Spintronics and pseudospintronics in graphene and topological insulators - nmat3305.pdf:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/MTTNKC5S/nmat3305.pdf:application/pdf},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{culcer_two-dimensional_2010,
 author = {Culcer, Dimitrie and Hwang, E.H. and Stanescu, Tudor D. and Das Sarma, S.},
 title = {Two-dimensional surface charge transport in topological insulators},
 volume = {82},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.82.155457},
 
 timestamp = {2017-07-10T14:26:27Z},
 number = {15},
 urldate = {2017-07-10},
 url = {https://doi.org/10.1103/physrevb.82.155457},
 journal = {Phys. Rev. B},
 month = oct,
 year = {2010},
 file = {PhysRevB.82.155457:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/VZJAAZDV/PhysRevB.82.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{mahfouzi_antidamping_2016,
 author = {Mahfouzi, Farzad and Nikolić, Branislav K. and Kioussis, Nicholas},
 title = {Antidamping spin-orbit torque driven by spin-flip reflection mechanism on the surface of a topological insulator: {A} time-dependent nonequilibrium Green function approach},
 volume = {93},
 issn = {2469-9950, 2469-9969},
 pages = {115419},
 doi = {10.1103/physrevb.93.115419},
 timestamp = {2017-07-31T11:06:13Z},
 number = {11},
 urldate = {2017-07-31},
 url = {https://doi.org/10.1103/physrevb.93.115419},
 journal = {Phys. Rev. B},
 month = mar,
 year = {2016},
 file = {PhysRevB.93.115419:/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/WH8JVRKU/PhysRevB.93.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{tserkovnyak_thin-film_2012-1,
 author = {Tserkovnyak, Yaroslav and Loss, Daniel},
 title = {Thin-Film Magnetization Dynamics on the Surface of a Topological Insulator},
 volume = {108},
 issn = {0031-9007, 1079-7114},
 doi = {10.1103/physrevlett.108.187201},
 pages = {187201},
 timestamp = {2017-07-28T13:25:17Z},
 number = {18},
 urldate = {2017-07-28},
 url = {https://doi.org/10.1103/physrevlett.108.187201},
 journal = {Phys. Rev. Lett.},
 month = apr,
 year = {2012},
 file = {untitled - PhysRevLett.108.187201:/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/ESV6FEI5/PhysRevLett.108.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{mahfouzi_spin-orbit_2012,
 author = {Mahfouzi, Farzad and Nagaosa, Naoto and Nikolić, Branislav K.},
 title = {Spin-Orbit Coupling Induced Spin-Transfer Torque and Current Polarization in Topological-{Insulator/Ferromagnet} Vertical Heterostructures},
 volume = {109},
 issn = {0031-9007, 1079-7114},
 doi = {10.1103/physrevlett.109.166602},
 pages = {166602},
 timestamp = {2017-07-28T13:25:20Z},
 number = {16},
 urldate = {2017-07-28},
 url = {https://doi.org/10.1103/physrevlett.109.166602},
 journal = {Phys. Rev. Lett.},
 month = oct,
 year = {2012},
 file = {untitled - PhysRevLett.109.166602:/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/A5ZW9XAR/PhysRevLett.109.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{aronov1989nuclear,
 author = {Aronov, AG and Lyanda-Geller, Yu B},
 title = {Nuclear electric resonance and orientation of carrier spins by an electric field},
 journal = {JETP Letters},
 volume = {50},
 pages = {431},
 year = {1989},
}

@article{dyakonov_current-induced_1971,
 author = {Dyakonov, M.I. and Perel, V.I.},
 title = {Current-induced spin orientation of electrons in semiconductors},
 volume = {35},
 issn = {0375-9601},
 url = {https://doi.org/10.1016/0375-9601(71)90196-4},
 doi = {10.1016/0375-9601(71)90196-4},
 abstract = {An electrical current in a semiconductor induces spin orientation in a thin layer near the surface of the sample due to spin-orbit effects in scattering of electrons. A weak magnetic field parallel to the current destroys this orientation.},
 number = {6},
 urldate = {2018-01-22},
 journal = {Phys. Lett. A},
 month = jul,
 year = {1971},
 pages = {459-460},
 annote = {spin hall effect},
 file = {ScienceDirect Full Text PDF:/home/rsokolewicz/Zotero/storage/CT2BL878/Dyakonov and Perel - 1971 - Current-induced spin orientation of electrons in s.pdf:application/pdf;ScienceDirect Snapshot:/home/rsokolewicz/Zotero/storage/UHIRC52T/0375960171901964.html:text/html},
 source = {Crossref},
 publisher = {Elsevier BV},
}

@article{hirsch_spin_1999,
 author = {Hirsch, J.E.},
 title = {Spin Hall Effect},
 volume = {83},
 url = {https://doi.org/10.1103/physrevlett.83.1834},
 doi = {10.1103/physrevlett.83.1834},
 abstract = {It is proposed that when a charge current circulates in a paramagnetic metal a transverse spin imbalance will be generated, giving rise to a ``spin Hall voltage.'' Similarly, it is proposed that when a spin current circulates a transverse charge imbalance will be generated, giving rise to a Hall voltage, in the absence of charge current and magnetic field. Based on these principles we propose an experiment to generate and detect a spin current in a paramagnetic metal.},
 number = {9},
 urldate = {2018-01-22},
 journal = {Phys. Rev. Lett.},
 month = aug,
 year = {1999},
 pages = {1834-1837},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/8EZVS8HM/PhysRevLett.83.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{ivchenko1978new,
 author = {Ivchenko, EL and Pikus, G},
 title = {New photogalvanic effect in gyrotropic crystals},
 url = {http://www.jetpletters.ac.ru/ps/1554/article_23792.pdf},
 journal = {JETP Lett},
 volume = {27},
 number = {11},
 pages = {604--608},
 year = {1978},
}

@article{edelstein_spin_1990,
 author = {Edelstein, V.M.},
 title = {Spin polarization of conduction electrons induced by electric current in two-dimensional asymmetric electron systems},
 volume = {73},
 issn = {0038-1098},
 url = {https://doi.org/10.1016/0038-1098(90)90963-c},
 doi = {10.1016/0038-1098(90)90963-c},
 number = {3},
 journal = {Solid State Commun.},
 year = {1990},
 pages = {233-235},
 source = {Crossref},
 publisher = {Elsevier BV},
 month = jan,
}

@article{wang_diffusive_2012,
 author = {Wang, Xuhui and Manchon, Aurelien},
 title = {Diffusive Spin Dynamics in Ferromagnetic Thin Films with a Rashba Interaction},
 volume = {108},
 issn = {0031-9007, 1079-7114},
 url = {https://doi.org/10.1103/physrevlett.108.117201},
 doi = {10.1103/physrevlett.108.117201},
 
 number = {11},
 urldate = {2017-07-31},
 journal = {Phys. Rev. Lett.},
 month = mar,
 year = {2012},
 file = {untitled - PhysRevLett.108.117201:/home/rsokolewicz/Zotero/storage/E5DKXFD6/PhysRevLett.108.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{qi_fractional_2008,
 author = {Qi, Xiao-Liang and Hughes, Taylor L. and Zhang, Shou-Cheng},
 title = {Fractional charge and quantized current in the quantum spin Hall state},
 volume = {4},
 copyright = {2008 Nature Publishing Group},
 issn = {1745-2473, 1745-2481},
 url = {https://doi.org/10.1038/nphys913},
 doi = {10.1038/nphys913},
 abstract = {{\textless }p{\textgreater }Quantum spin Hall insulators are new states of matter that were recently predicted and observed. A theoretical work now explores distinct experimental manifestations resulting from the exotic behaviour that characterizes these structures.{\textless }/p{\textgreater }},
 
 number = {4},
 urldate = {2018-02-04},
 journal = {Nat. Phys.},
 month = mar,
 year = {2008},
 pages = {273-276},
 file = {Full Text PDF:/home/rsokolewicz/Zotero/storage/4Q8YSXZ6/Qi et al. - 2008 - Fractional charge and quantized current in the qua.pdf:application/pdf;Snapshot:/home/rsokolewicz/Zotero/storage/HUJUQRQM/nphys913.html:text/html},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{yokoyama_anomalous_2010,
 author = {Yokoyama, Takehito and Tanaka, Yukio and Nagaosa, Naoto},
 title = {Anomalous magnetoresistance of a two-dimensional ferromagnet/ferromagnet junction on the surface of a topological insulator},
 volume = {81},
 issn = {1098-0121, 1550-235X},
 url = {https://doi.org/10.1103/physrevb.81.121401},
 doi = {10.1103/physrevb.81.121401},
 
 number = {12},
 urldate = {2018-01-31},
 journal = {Phys. Rev. B},
 month = mar,
 year = {2010},
 file = {PhysRevB.81.pdf:/home/rsokolewicz/Zotero/storage/VB7B5T2W/PhysRevB.81.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{stiles_anatomy_2002,
 author = {Stiles, M.D. and Zangwill, A.},
 title = {Anatomy of spin-transfer torque},
 volume = {66},
 url = {https://doi.org/10.1103/physrevb.66.014407},
 doi = {10.1103/physrevb.66.014407},
 abstract = {Spin-transfer torques occur in magnetic heterostructures because the transverse component of a spin current that flows from a nonmagnet into a ferromagnet is absorbed at the interface. We demonstrate this fact explicitly using free-electron models and first-principles electronic structure calculations for real material interfaces. Three distinct processes contribute to the absorption: (1) spin-dependent reflection and transmission, (2) rotation of reflected and transmitted spins, and (3) spatial precession of spins in the ferromagnet. When summed over all Fermi surface electrons, these processes reduce the transverse component of the transmitted and reflected spin currents to nearly zero for most systems of interest. Therefore, to a good approximation, the torque on the magnetization is proportional to the transverse piece of the incoming spin current.},
 number = {1},
 urldate = {2018-01-31},
 journal = {Phys. Rev. B},
 month = jun,
 year = {2002},
 pages = {014407},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/PYHBV2U6/PhysRevB.66.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0163-1829, 1095-3795},
}

@article{ralph_spin_2008,
 author = {Ralph, D.C. and Stiles, M.D.},
 title = {Spin transfer torques},
 volume = {320},
 issn = {0304-8853},
 url = {https://doi.org/10.1016/j.jmmm.2007.12.019},
 doi = {10.1016/j.jmmm.2007.12.019},
 
 number = {7},
 urldate = {2017-03-16},
 journal = {J. Magn. Magn. Mater.},
 month = apr,
 year = {2008},
 pages = {1190-1216},
 file = {doi\:10.1016/j.jmmm.2007.12.019 - JMMM-320-1190-2008.pdf:/home/rsokolewicz/Zotero/storage/CPUCTPVU/JMMM-320-1190-2008.pdf:application/pdf},
 source = {Crossref},
 publisher = {Elsevier BV},
}

@article{haney_current_2013,
 author = {Haney, Paul M. and Lee, Hyun-Woo and Lee, Kyung-Jin and Manchon, Aurélien and Stiles, M.D.},
 title = {Current induced torques and interfacial spin-orbit coupling: {Semiclassical} modeling},
 volume = {87},
 issn = {1098-0121, 1550-235X},
 
 url = {https://doi.org/10.1103/physrevb.87.174411},
 doi = {10.1103/physrevb.87.174411},
 pages = {174411},
 number = {17},
 urldate = {2017-07-31},
 journal = {Phys. Rev. B},
 month = may,
 year = {2013},
 file = {PhysRevB.87.174411:/home/rsokolewicz/Zotero/storage/SCV8M973/PhysRevB.87.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{duine_functional_2007,
 author = {Duine, R.A. and Núñez, A.S. and Sinova, Jairo and MacDonald, A.H.},
 title = {Functional Keldysh theory of spin torques},
 volume = {75},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.75.214420},
 abstract = {We present a microscopic treatment of current-induced torques and thermal fluctuations in itinerant ferromagnets based on a functional formulation of the Keldysh formalism. We find that the nonequilibrium magnetization dynamics is governed by a stochastic Landau-Lifschitz-Gilbert equation with spin transfer torques. We calculate the Gilbert damping parameter \$\alpha\$ and the non-adiabatic spin transfer torque parameter \$\beta\$ for a model ferromagnet. We find that \$\beta \neq \alpha\$, in agreement with the results obtained using imaginary-time methods of Kohno, Tatara and Shibata [J. Phys. Soc. Japan 75, 113706 (2006)]. We comment on the relationship between \$$s$--$d$\$ and isotropic-Stoner toy models of ferromagnetism and more realistic density-functional-theory models, and on the implications of these relationships for predictions of the \$\beta/\alpha\$ ratio which plays a central role in domain wall motion. Only for a single-parabolic-band isotropic-Stoner model with an exchange splitting that is small compared to the Fermi energy does \$\beta/\alpha\$ approach one. In addition, our microscopic formalism incorporates naturally the fluctuations needed in a nonzero-temperature description of the magnetization. We find that to first order in the applied electric field, the usual form of thermal fluctuations via a phenomenological stochastic magnetic field holds.},
 timestamp = {2017-06-15T12:36:38Z},
 archiveprefix = {arXiv},
 eprinttype = {arxiv},
 eprint = {cond-mat/0703414},
 number = {21},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1103/physrevb.75.214420},
 journal = {Phys. Rev. B},
 month = jun,
 year = {2007},
 keywords = {Condensed Matter - Mesoscale and Nanoscale Physics},
 file = {arXiv\:cond-mat/0703414 PDF:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/8EUZJR7D/Duine et al. - 2007 - Functional Keldysh Theory of Spin Torques.pdf:application/pdf;arXiv.org Snapshot:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/BUQQ3VAB/0703414.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{berger_emission_1996,
 author = {Berger, L.},
 title = {Emission of spin waves by a magnetic multilayer traversed by a current},
 volume = {54},
 url = {https://doi.org/10.1103/physrevb.54.9353},
 number = {13},
 urldate = {2017-09-29},
 journal = {Phys. Rev. B},
 year = {1996},
 pages = {9353-9358},
 file = {PhysRevB.54.pdf:/home/rsokolewicz/Zotero/storage/JQPSFSLZ/PhysRevB.54.pdf:application/pdf},
 doi = {10.1103/physrevb.54.9353},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0163-1829, 1095-3795},
 month = oct,
}

@article{slonczewski_current-driven_1996,
 author = {Slonczewski, J.C.},
 title = {Current-driven excitation of magnetic multilayers},
 volume = {159},
 url = {https://doi.org/10.1016/0304-8853(96)00062-5},
 number = {1-2},
 urldate = {2017-09-29},
 journal = {J. Magn. Magn. Mater.},
 year = {1996},
 pages = {L1-L7},
 file = {1-s2.0-0304885396000625-main.pdf:/home/rsokolewicz/Zotero/storage/YDG3GP76/1-s2.0-0304885396000625-main.pdf:application/pdf},
 doi = {10.1016/0304-8853(96)00062-5},
 source = {Crossref},
 publisher = {Elsevier BV},
 issn = {0304-8853},
 month = jun,
}

@article{tatara_microscopic_2008,
 author = {Tatara, Gen and Kohno, Hiroshi and Shibata, Junya},
 title = {Microscopic approach to current-driven domain wall dynamics},
 volume = {468},
 issn = {0370-1573},
 doi = {10.1016/j.physrep.2008.07.003},
 
 timestamp = {2017-07-31T15:54:44Z},
 number = {6},
 urldate = {2017-07-31},
 url = {https://doi.org/10.1016/j.physrep.2008.07.003},
 journal = {Phys. Rep.},
 month = nov,
 year = {2008},
 pages = {213-301},
 file = {Microscopic approach to current-driven domain wall dynamics - 1-s2.0-S0370157308002597-main.pdf:/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/FE9Z7QP2/1-s2.0-S0370157308002597-main.pdf:application/pdf},
 source = {Crossref},
 publisher = {Elsevier BV},
}

@article{hasan_colloquium_2010,
 author = {Hasan, M.Z. and Kane, C.L.},
 title = {Colloquium: {Topological} insulators},
 volume = {82},
 url = {https://doi.org/10.1103/revmodphys.82.3045},
 doi = {10.1103/revmodphys.82.3045},
 abstract = {Topological insulators are electronic materials that have a bulk band gap like an ordinary insulator but have protected conducting states on their edge or surface. These states are possible due to the combination of spin-orbit interactions and time-reversal symmetry. The two-dimensional (2D) topological insulator is a quantum spin Hall insulator, which is a close cousin of the integer quantum Hall state. A three-dimensional (3D) topological insulator supports novel spin-polarized 2D Dirac fermions on its surface. In this Colloquium the theoretical foundation for topological insulators and superconductors is reviewed and recent experiments are described in which the signatures of topological insulators have been observed. Transport experiments on HgTe/CdTe quantum wells are described that demonstrate the existence of the edge states predicted for the quantum spin Hall insulator. Experiments on Bi1$-$xSbx, Bi2Se3, Bi2Te3, and Sb2Te3 are then discussed that establish these materials as 3D topological insulators and directly probe the topology of their surface states. Exotic states are described that can occur at the surface of a 3D topological insulator due to an induced energy gap. A magnetic gap leads to a novel quantum Hall state that gives rise to a topological magnetoelectric effect. A superconducting energy gap leads to a state that supports Majorana fermions and may provide a new venue for realizing proposals for topological quantum computation. Prospects for observing these exotic states are also discussed, as well as other potential device applications of topological insulators.},
 number = {4},
 urldate = {2017-10-16},
 journal = {Rev. Mod. Phys.},
 month = nov,
 year = {2010},
 pages = {3045-3067},
 file = {APS Snapshot:/home/rsokolewicz/Zotero/storage/RNUPRLW6/RevModPhys.82.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0034-6861, 1539-0756},
}

@article{pesin_quantum_2012,
 author = {Pesin, D.A. and MacDonald, A.H.},
 title = {Quantum kinetic theory of current-induced torques in Rashba ferromagnets},
 volume = {86},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.86.014416},
 
 timestamp = {2017-06-15T12:45:47Z},
 number = {1},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1103/physrevb.86.014416},
 journal = {Phys. Rev. B},
 month = jul,
 year = {2012},
 file = {PhysRevB.86.014416:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/XPH4D894/PhysRevB.86.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{manchon2009theory,
 author = {Manchon, A. and Zhang, S.},
 title = {Theory of spin torque due to spin-orbit coupling},
 journal = {Phys. Rev. B},
 volume = {79},
 number = {9},
 pages = {094422},
 year = {2009},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.79.094422},
 source = {Crossref},
 url = {https://doi.org/10.1103/physrevb.79.094422},
 issn = {1098-0121, 1550-235X},
 month = mar,
}

@article{miron_current-driven_2010,
 author = {Mihai Miron, Ioan and Gaudin, Gilles and Auffret, Stéphane and Rodmacq, Bernard and Schuhl, Alain and Pizzini, Stefania and Vogel, Jan and Gambardella, Pietro},
 title = {Current-driven spin torque induced by the Rashba effect in a ferromagnetic metal layer},
 volume = {9},
 copyright = {2010 Nature Publishing Group},
 issn = {1476-1122, 1476-4660},
 url = {https://doi.org/10.1038/nmat2613},
 doi = {10.1038/nmat2613},
 abstract = {{\textless }p{\textgreater }Control of magnetization in ferromagnetic metals can be achieved through the spin torque of currents of spin-polarized electrons, usually injected externally. It is now shown that even without this spin-polarized injection, a current can induce strong spin torques through the Rashba effect. The efficiency of this process makes it a realistic candidate for room-temperature spintronic applications.{\textless }/p{\textgreater }},
 
 number = {3},
 urldate = {2018-02-01},
 journal = {Nat. Mater.},
 month = jan,
 year = {2010},
 pages = {230-234},
 file = {Full Text PDF:/home/rsokolewicz/Zotero/storage/VM5JIQ59/Miron et al. - 2010 - Current-driven spin torque induced by the Rashba e.pdf:application/pdf;Snapshot:/home/rsokolewicz/Zotero/storage/63CXJ4HA/nmat2613.html:text/html},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{manchon_theory_2008,
 author = {Manchon, A. and Zhang, S.},
 title = {Theory of nonequilibrium intrinsic spin torque in a single nanomagnet},
 volume = {78},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.78.212405},
 pages = {212405},
 timestamp = {2017-06-15T12:45:49Z},
 number = {21},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1103/physrevb.78.212405},
 journal = {Phys. Rev. B},
 month = dec,
 year = {2008},
 file = {PhysRevB.78.212405:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/UE9TFS4D/PhysRevB.78.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{obata_current-induced_2008,
 author = {Obata, Katsunori and Tatara, Gen},
 title = {Current-induced domain wall motion in Rashba spin-orbit system},
 volume = {77},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.77.214429},
 
 timestamp = {2017-06-15T12:45:51Z},
 number = {21},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1103/physrevb.77.214429},
 journal = {Phys. Rev. B},
 month = jun,
 year = {2008},
 file = {PhysRevB.77.214429:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/BX6ZT75N/PhysRevB.77.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{xiao_semiclassical_2017,
 author = {Xiao, Cong and Niu, Qian},
 title = {Semiclassical theory of spin-orbit torques in disordered multiband electron systems},
 abstract = {We study spin-orbit torques (SOT) in non-degenerate multiband electron systems in the weak disorder limit. Using the two-dimensional Rashba ferromagnet as a model system, we show that the antidamping-like SOT arising from disorder-induced interband-coherence effects is very sensitive to the spin structure of disorder and may have the same sign as the intrinsic SOT in the presence of spin-dependent disorder. While the cancellation of this SOT and the intrinsic one occurs only in the case of spin-independent short-range disorder. In order to have better physical transparency a semiclassical Boltzmann approach equivalent to the Kubo diagrammatic approach in the non- crossing approximation is formulated. This semiclassical framework accounts for the interband- coherence effects induced by both the electric field and static impurity scattering.},
 timestamp = {2017-06-15T14:51:16Z},
 archiveprefix = {arXiv},
 eprinttype = {arxiv},
 eprint = {1705.07947},
 primaryclass = {cond-mat},
 urldate = {2017-06-15},
 url = {https://doi.org/10.1103/physrevb.96.045428},
 journal = {Phys. Rev. B},
 month = jul,
 year = {2017},
 keywords = {Condensed Matter - Mesoscale and Nanoscale Physics},
 file = {arXiv\:1705.07947 PDF:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/NGRRI4MR/Xiao and Niu - 2017 - Semiclassical theory of spin-orbit torques in diso.pdf:application/pdf;arXiv.org Snapshot:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/BT2TKEA9/1705.html:text/html},
 doi = {10.1103/physrevb.96.045428},
 number = {4},
 source = {Crossref},
 volume = {96},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{tserkovnyak_theory_2009,
 author = {Tserkovnyak, Yaroslav and Wong, Clement H.},
 title = {Theory of spin magnetohydrodynamics},
 volume = {79},
 doi = {10.1103/physrevb.79.014402},
 abstract = {We develop a phenomenological hydrodynamic theory of coherent magnetic precession coupled to electric currents. Exchange interaction between electron spin and collective magnetic texture produces two reciprocal effects: spin-transfer torque on the magnetic order parameter and the Berry-phase gauge field experienced by the itinerant electrons. The dissipative processes are governed by three coefficients: the ohmic resistance, Gilbert damping of the magnetization, and the ``$\beta$ coefficient'' describing viscous coupling between magnetic dynamics and electric current, which stems from spin mistracking of the magnetic order. We develop general magnetohydrodynamic equations and discuss the net dissipation produced by the coupled dynamics. The latter in particular allows us to determine a lower bound on the magnetic-texture resistivity.},
 timestamp = {2017-07-02T09:14:20Z},
 number = {1},
 urldate = {2017-07-02},
 url = {https://doi.org/10.1103/physrevb.79.014402},
 journal = {Phys. Rev. B},
 month = jan,
 year = {2009},
 pages = {014402},
 file = {APS Snapshot:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/93HX6R9K/PhysRevB.79.html:text/html},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{garate_influence_2009,
 author = {Garate, Ion and MacDonald, A.H.},
 title = {Influence of a transport current on magnetic anisotropy in gyrotropic ferromagnets},
 volume = {80},
 issn = {1098-0121, 1550-235X},
 doi = {10.1103/physrevb.80.134403},
 pages = {134403},
 timestamp = {2017-07-10T09:46:58Z},
 number = {13},
 urldate = {2017-07-10},
 url = {https://doi.org/10.1103/physrevb.80.134403},
 journal = {Phys. Rev. B},
 month = oct,
 year = {2009},
 file = {PhysRevB.80.134403:/home/rsokolewicz/.mozilla/firefox/s6puzc7s.default-1496144780566/zotero/storage/QDSFCFRB/PhysRevB.80.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@book{bentley:1999,
 author = {Bentley, Jon},
 title = {{{P}rogramming} {{P}earls}},
 publisher = {Ad\-dison--Wesley},
 year = {1999},
 address = {Boston, MA, USA},
 edition = {2},
}

@book{bringhurst:2002,
 author = {Bringhurst, Robert},
 title = {{{T}he} {{E}lements} of {{T}ypographic} {{S}tyle}},
 publisher = {Hartley  \&  Marks Publishers},
 year = {2013},
 series = {Version 4.0: 20th Anniversary Edition},
 address = {Point Roberts, WA, USA},
}

@book{cormen:2001,
 author = {Cormen, Thomas H. and Leiserson, Charles E. and Rivest, Ronald and Stein, Clifford},
 title = {Algorithmen - Eine Einf\"uhrung},
 publisher = {De Gruyter},
 year = {2017},
 address = {Cambridge, MA, USA},
 edition = {3},
 doi = {10.1515/9783110522013},
 source = {Crossref},
 url = {https://doi.org/10.1515/9783110522013},
 isbn = {9783110522013},
 month = jan,
}

@book{dueck:trio,
 author = {Dueck, Gunter},
 title = {{{D}ueck's} {{T}rilogie} 2.1: {{O}mnisophie} -- {{S}upramanie} -- {{T}opothesie}},
 publisher = {Springer},
 address = {Berlin, Germany},
 year = {2013},
}

@article{knuth:1976,
 author = {Knuth, Donald E.},
 title = {{{B}ig} {{O}micron} and {{B}ig} {{O}mega} and {{B}ig} {{T}heta}},
 journal = {SIGACT News},
 year = {1976},
 volume = {8},
 pages = {18--24},
 number = {2},
 address = {New York, NY, USA},
 publisher = {ACM Press},
}

@article{knuth:1974,
 author = {Knuth, Donald E.},
 title = {Computer programming as an art},
 journal = {Commun. ACM},
 year = {1974},
 volume = {17},
 pages = {667-673},
 number = {12},
 address = {New York, NY, USA},
 publisher = {Association for Computing Machinery (ACM)},
 doi = {10.1145/361604.361612},
 source = {Crossref},
 url = {https://doi.org/10.1145/361604.361612},
 issn = {0001-0782},
 month = dec,
}

@book{sommerville:1992,
 author = {Sommerville, Ian},
 title = {{{S}oftware} {{E}ngineering}},
 publisher = {Addison-Wesley},
 year = {2015},
 address = {Boston, MA, USA},
 edition = {10},
}

@book{taleb:2018,
 author = {Taleb, Nassim Nicholas},
 title = {Skin in the Game: {Hidden} Asymmetries in Daily Life},
 publisher = {Random House},
 year = {2018},
 address = {New York, NY, USA},
}

@book{taleb:2010,
 author = {Lybeck, Eric},
 title = {The Black Swan},
 publisher = {Macat Library},
 year = {2017},
 address = {New York, NY, USA},
 doi = {10.4324/9781912281206},
 source = {Crossref},
 url = {https://doi.org/10.4324/9781912281206},
 subtitle = {the Impact of the Highly Improbable},
 isbn = {9781912281206},
 month = jul,
}

@book{ferriss:2016,
 author = {Ferriss, Timothy},
 title = {Tools of Titans: {The} Tactics, Routines, and Habits of Billionaires, Icons, and World-Class Performers},
 publisher = {Houghton Mifflin Harcourt},
 year = {2016},
 address = {Boston, MA, USA},
}

@book{adams:1996,
 author = {Adams, Scott},
 title = {The {Dilbert} Principle},
 publisher = {Harper Business},
 year = {1996},
 address = {New York, NY, USA},
}

@book{adams:2013,
 author = {Adams, Scott},
 title = {How to Fail at Almost Everything and Still Win Big: {Kind} of the Story of My Life},
 publisher = {Portfolio Penguin},
 year = {2013},
 address = {London, United Kingdom},
}

@book{aurelius:2002,
 author = {Aurelius, Marcus},
 title = {Meditations {(A} New Translation)},
 publisher = {Modern Library},
 year = {2002},
 address = {New York, NY, USA},
}

@book{cialdini:1984,
 author = {Gass, Robert H. and Seiter, John S.},
 title = {Persuasion},
 publisher = {Routledge},
 year = {2018},
 address = {New York, NY, USA},
 doi = {10.4324/9781315209302},
 source = {Crossref},
 url = {https://doi.org/10.4324/9781315209302},
 subtitle = {Social Influence and Compliance Gaining},
 isbn = {9781315209302},
 month = jan,
}

@book{feynman:1985,
 author = {Feynman, Richard P.},
 title = {{{S}urely} {{Y}ou're} {{J}oking,} {{M}r.} {{F}eynman:} {{A}dventures} of a {{C}urious} {{C}haracter}},
 publisher = {W. W. Norton},
 year = {1985},
 address = {New York, NY, USA},
}

@book{greenwald:2014,
 author = {Greenwald, Glenn},
 title = {{{N}o} {{P}lace} to {{H}ide:} {{E}dward} {{S}nowden,} the {{NSA},} and the {{S}urveillance} {{S}tate}},
 publisher = {Metropolitan Books},
 year = {2014},
 address = {New York, NY, USA},
}

@book{orwell:1949,
 author = {Orwell, George},
 title = {Nineteen Eighty-Four},
 publisher = {Secker  \&  Warburg},
 year = {1949},
 address = {London, United Kingdom},
}

@book{pausch:2008,
 author = {Pausch, Randy},
 editor = {Zaslow, Jeffrey},
 title = {The Last Lecture},
 publisher = {Hodder  \&  Stoughton},
 year = {2008},
 address = {London, United Kingdom},
}

@book{seneca,
 author = {Seneca, Lucius},
 title = {Letters from a Stoic: {Epistulae} {Morales} ad Lucilium},
 publisher = {Penguin},
 year = {1969},
 address = {Harmondsworth, United Kingdom},
}

@book{trump:1987,
 author = {Trump, Donald J. and Schwartz, Tony},
 title = {Trump: {The} Art of the Deal},
 publisher = {Random House},
 year = {1987},
 address = {New York, NY, USA},
}

@book{frankl:1959,
 author = {Frankl, Viktor E.},
 title = {Man's Search for Meaning},
 publisher = {Beacon Press},
 year = {1959},
 address = {Boston, MA, USA},
}

@book{munger:2008,
 author = {Munger, Charles T.},
 editor = {Kaufman, Peter D.},
 title = {Poor {Charlie's} Almanack: {The} Wit and Wisdom of {Charles} T. Munger},
 publisher = {Donning Company},
 year = {2008},
 address = {Virginia Beach, VA, USA},
 edition = {3},
}

@book{postman:,
 author = {Postman, Neil},
 title = {Amusing Ourselves to Death: {Public} Discourse in the Age of Show Business (20th Anniversary Edition)},
 publisher = {Penguin Books},
 year = {},
 address = {New York, NY, USA},
}

@book{taleb:2012,
 author = {Taleb, Nassim Nicholas},
 title = {Der Schwarze Schwan},
 publisher = {Carl Hanser Verlag GmbH  \& amp; Co. KG},
 year = {2008},
 address = {New York, NY, USA},
 doi = {10.3139/9783446419377},
 source = {Crossref},
 url = {https://doi.org/10.3139/9783446419377},
 subtitle = {Die Macht h\"ochst unwahrscheinlicher Ereignisse},
 isbn = {9783446415683, 9783446419377},
 month = oct,
}

@book{peterson:2018,
 author = {Peterson, Jordan B.},
 title = {12 Rules for Life: {An} Antidote to Chaos},
 publisher = {Random House Canada},
 year = {2018},
 address = {Toronto, ON, Canada},
}

@book{harari:2014,
 author = {Harari, Yuval Noah},
 title = {Sapiens: {A} Brief History of Humankind},
 publisher = {Random House},
 year = {2014},
 address = {New York, NY, USA},
}

@article{Ralph2011SOTFMresonance,
 author = {Liu, Luqiao and Moriyama, Takahiro and Ralph, D.C. and Buhrman, R.A.},
 title = {Spin-Torque Ferromagnetic Resonance Induced by the Spin Hall Effect},
 journal = {Phys. Rev. Lett.},
 volume = {106},
 issue = {3},
 pages = {036601},
 numpages = {4},
 year = {2011},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.106.036601},
 url = {https://doi.org/10.1103/physrevlett.106.036601},
 number = {3},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
 month = jan,
}

@article{Wang2015_SOTHflCoFEBIMgO,
 author = {Akyol, Mustafa and Yu, Guoqiang and Alzate, Juan G. and Upadhyaya, Pramey and Li, Xiang and Wong, Kin L. and Ekicibil, Ahmet and Khalili Amiri, Pedram and Wang, Kang L.},
 title = {Current-induced spin-orbit torque switching of perpendicularly magnetized {Hf|CoFeB|MgO} and {Hf|CoFeB|TaOx} structures},
 journal = {Appl. Phys. Lett.},
 volume = {106},
 number = {16},
 pages = {162409},
 year = {2015},
 doi = {10.1063/1.4919108},
 url = {https://doi.org/10.1063/1.4919108},
 eprint = {https://doi.org/10.1063/1.4919108},
 source = {Crossref},
 publisher = {AIP Publishing},
 issn = {0003-6951, 1077-3118},
 month = apr,
}

@article{Ralph2016SOTWTE2,
 author = {MacNeill, D. and Stiehl, G.M. and Guimaraes, M.H.D. and Buhrman, R.A. and Park, J. and Ralph, D.C.},
 date = {2016/11/07/online},
 date-added = {2019-01-22 14:34:33 +0100},
 date-modified = {2019-01-22 14:34:33 +0100},
 day = {07},
 journal = {Nat. Phys.},
 m3 = {Article},
 publisher = {Springer Science and Business Media LLC},
 title = {Control of spin--orbit torques through crystal symmetry in {WTe2/ferromagnet} bilayers},
 ty = {JOUR},
 url = {https://doi.org/10.1038/nphys3933},
 volume = {13},
 year = {2016},
 bdsk-url-1 = {https://doi.org/10.1038/nphys3933},
 doi = {10.1038/nphys3933},
 number = {3},
 pages = {300-305},
 source = {Crossref},
 issn = {1745-2473, 1745-2481},
 month = nov,
}

@article{Ralph2018SOT,
 author = {Guimarães, Marcos H.D. and Stiehl, Gregory M. and MacNeill, David and Reynolds, Neal D. and Ralph, Daniel C.},
 title = {Spin--Orbit Torques in {NbSe2/Permalloy} Bilayers},
 journal = {Nano Lett.},
 volume = {18},
 number = {2},
 pages = {1311-1316},
 year = {2018},
 doi = {10.1021/acs.nanolett.7b04993},
 url = {https://doi.org/10.1021/acs.nanolett.7b04993},
 eprint = {https://doi.org/10.1021/acs.nanolett.7b04993},
 source = {Crossref},
 publisher = {American Chemical Society (ACS)},
 issn = {1530-6984, 1530-6992},
 month = jan,
}

@article{Cha2018,
 author = {Cha, Soonyoung and Noh, Minji and Kim, Jehyun and Son, Jangyup and Bae, Hyemin and Lee, Doeon and Kim, Hoil and Lee, Jekwan and Shin, Ho-Seung and Sim, Sangwan and Yang, Seunghoon and Lee, Sooun and Shim, Wooyoung and Lee, Chul-Ho and Jo, Moon-Ho and Kim, Jun Sung and Kim, Dohun and Choi, Hyunyong},
 abstract = {Quantum optoelectronic devices capable of isolating a target degree of freedom (DoF) from other DoFs have allowed for new applications in modern information technology. Many works on solid-state spintronics have focused on methods to disentangle the spin DoF from the charge DoF1, yet many related issues remain unresolved. Although the recent advent of atomically thin transition metal dichalcogenides (TMDs) has enabled the use of valley pseudospin as an alternative DoF2,3, it is nontrivial to separate the spin DoF from the valley DoF since the time-reversal valley DoF is intrinsically locked with the spin DoF4. Here, we demonstrate lateral TMD--graphene--topological insulator hetero-devices with the possibility of such a DoF-selective measurement. We generate the valley-locked spin DoF via a circular photogalvanic effect in an electric-double-layer WSe2 transistor. The valley-locked spin photocarriers then diffuse in a submicrometre-long graphene layer, and the spin DoF is measured separately in the topological insulator via non-local electrical detection using the characteristic spin--momentum locking. Operating at room temperature, our integrated devices exhibit a non-local spin polarization degree of higher than 0.5, providing the potential for coupled opto-spin--valleytronic applications that independently exploit the valley and spin DoFs.},
 da = {2018/07/23},
 date-added = {2018-09-05 08:27:14 +0200},
 date-modified = {2018-09-05 08:27:31 +0200},
 doi = {10.1038/s41565-018-0195-y},
 id = {Cha2018},
 journal = {Nat. Nanotechnol.},
 title = {Generation, transport and detection of valley-locked spin photocurrent in {WSe2}--graphene--{Bi2Se3} heterostructures},
 ty = {JOUR},
 url = {https://doi.org/10.1038/s41565-018-0195-y},
 year = {2018},
 bdsk-url-1 = {https://doi.org/10.1038/s41565-018-0195-y},
 number = {10},
 pages = {910-914},
 source = {Crossref},
 volume = {13},
 publisher = {Springer Science and Business Media LLC},
 issn = {1748-3387, 1748-3395},
 month = jul,
}

@misc{sup,
 author = {see Supplementary Material},
 url = {},
}

@article{vanderBijl2012,
 author = {van der Bijl, E. and Duine, R.A.},
 title = {Current-induced torques in textured Rashba ferromagnets},
 journal = {Phys. Rev. B},
 volume = {86},
 issue = {9},
 pages = {094406},
 numpages = {9},
 year = {2012},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.86.094406},
 url = {https://doi.org/10.1103/physrevb.86.094406},
 number = {9},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
 month = sep,
}

@article{Hals2013,
 author = {Hals, Kjetil M.D. and Brataas, Arne},
 title = {Phenomenology of current-induced spin-orbit torques},
 journal = {Phys. Rev. B},
 volume = {88},
 issue = {8},
 pages = {085423},
 numpages = {5},
 year = {2013},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.88.085423},
 url = {https://doi.org/10.1103/physrevb.88.085423},
 number = {8},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
 month = aug,
}

@article{Fan_SOT_TI_2016,
 author = {Fan, Yabin and Kou, Xufeng and Upadhyaya, Pramey and Shao, Qiming and Pan, Lei and Lang, Murong and Che, Xiaoyu and Tang, Jianshi and Montazeri, Mohammad and Murata, Koichi and Chang, Li-Te and Akyol, Mustafa and Yu, Guoqiang and Nie, Tianxiao and Wong, Kin L. and Liu, Jun and Wang, Yong and Tserkovnyak, Yaroslav and Wang, Kang L.},
 day = {04},
 journal = {Nat. Nanotechnol.},
 m3 = {Article},
 publisher = {Springer Science and Business Media LLC},
 title = {Electric-field control of spin--orbit torque in a magnetically doped topological insulator},
 ty = {JOUR},
 url = {https://doi.org/10.1038/nnano.2015.294},
 volume = {11},
 year = {2016},
 bdsk-url-1 = {http://dx.doi.org/10.1038/nnano.2015.294},
 doi = {10.1038/nnano.2015.294},
 number = {4},
 pages = {352-359},
 source = {Crossref},
 issn = {1748-3387, 1748-3395},
 month = jan,
}

@article{wang_SOT_BiSe_2014,
 author = {Wang, Yi and Deorani, Praveen and Banerjee, Karan and Koirala, Nikesh and Brahlek, Matthew and Oh, Seongshik and Yang, Hyunsoo},
 title = {Topological Surface States Originated Spin-Orbit Torques {inBi2Se3}},
 journal = {Phys. Rev. Lett.},
 volume = {114},
 issue = {25},
 pages = {257202},
 numpages = {5},
 year = {2015},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.114.257202},
 url = {https://doi.org/10.1103/physrevlett.114.257202},
 number = {25},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
 month = jun,
}

@article{Yasuda_SOT_BiSbTe_2017,
 author = {Yasuda, K. and Tsukazaki, A. and Yoshimi, R. and Kondou, K. and Takahashi, K.S. and Otani, Y. and Kawasaki, M. and Tokura, Y.},
 title = {Current-Nonlinear Hall Effect and Spin-Orbit Torque Magnetization Switching in a Magnetic Topological Insulator},
 journal = {Phys. Rev. Lett.},
 volume = {119},
 issue = {13},
 pages = {137204},
 numpages = {5},
 year = {2017},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.119.137204},
 url = {https://doi.org/10.1103/physrevlett.119.137204},
 number = {13},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
 month = sep,
}

@article{kirilyuk_ultrafast_2010,
 author = {Kirilyuk, Andrei and Kimel, Alexey V. and Rasing, Theo},
 title = {Ultrafast optical manipulation of magnetic order},
 volume = {82},
 url = {https://doi.org/10.1103/revmodphys.82.2731},
 doi = {10.1103/revmodphys.82.2731},
 abstract = {The interaction of subpicosecond laser pulses with magnetically ordered materials has developed into a fascinating research topic in modern magnetism. From the discovery of subpicosecond demagnetization over a decade ago to the recent demonstration of magnetization reversal by a single 40fs laser pulse, the manipulation of magnetic order by ultrashort laser pulses has become a fundamentally challenging topic with a potentially high impact for future spintronics, data storage and manipulation, and quantum computation. Understanding the underlying mechanisms implies understanding the interaction of photons with charges, spins, and lattice, and the angular momentum transfer between them. This paper will review the progress in this field of laser manipulation of magnetic order in a systematic way. Starting with a historical introduction, the interaction of light with magnetically ordered matter is discussed. By investigating metals, semiconductors, and dielectrics, the roles of (nearly) free electrons, charge redistributions, and spin-orbit and spin-lattice interactions can partly be separated, and effects due to heating can be distinguished from those that are not. It will be shown that there is a fundamental distinction between processes that involve the actual absorption of photons and those that do not. It turns out that for the latter, the polarization of light plays an essential role in the manipulation of the magnetic moments at the femtosecond time scale. Thus, circularly and linearly polarized pulses are shown to act as strong transient magnetic field pulses originating from the nonabsorptive inverse Faraday and inverse Cotton-Mouton effects, respectively. The recent progress in the understanding of magneto-optical effects on the femtosecond time scale together with the mentioned inverse, optomagnetic effects promises a bright future for this field of ultrafast optical manipulation of magnetic order or femtomagnetism.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Rev. Mod. Phys.},
 year = {2010},
 pages = {2731-2784},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0034-6861, 1539-0756},
}

@article{roschewsky_spin-orbit_2017,
 author = {Roschewsky, Niklas and Lambert, Charles-Henri and Salahuddin, Sayeef},
 title = {Spin-orbit torque switching of ultralarge-thickness ferrimagnetic {GdFeCo}},
 volume = {96},
 url = {https://doi.org/10.1103/physrevb.96.064406},
 doi = {10.1103/physrevb.96.064406},
 abstract = {We report on spin-orbit torque measurements in ferrimagnetic Gd21(Fe90Co10)79 films with bulk perpendicular magnetic anisotropy and thicknesses up to 30nm. The dampinglike and fieldlike torques have been quantified using second harmonic Hall voltage detection. Both torques show an inverse linear dependence on the thickness that is indicative of the interfacial nature of the torques. The spin-Hall angle remains constant over the thickness range of 10 to 30nm Gd21(Fe90Co10)79. Remarkably, we find that this interfacial torque is able to switch a 30-nm-thick Gd21(Fe90Co10)79 film with a reasonably large thermal stability of ?100kBT.},
 number = {6},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = aug,
 year = {2017},
 pages = {064406},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{roschewsky_spin-orbit_2016,
 author = {Roschewsky, Niklas and Matsumura, Tomoya and Cheema, Suraj and Hellman, Frances and Kato, Takeshi and Iwata, Satoshi and Salahuddin, Sayeef},
 title = {Spin-orbit torques in ferrimagnetic {GdFeCo} alloys},
 volume = {109},
 issn = {0003-6951, 1077-3118},
 url = {https://doi.org/10.1063/1.4962812},
 doi = {10.1063/1.4962812},
 number = {11},
 urldate = {2019-11-20},
 journal = {Appl. Phys. Lett.},
 month = sep,
 year = {2016},
 pages = {112403},
 source = {Crossref},
 publisher = {AIP Publishing},
}

@article{kim_spin-orbit_2018,
 author = {Kim, JongHyuk and Lee, DongJoon and Lee, Kyung-Jin and Ju, Byeong-Kwon and Koo, Hyun Cheol and Min, Byoung-Chul and Lee, OukJae},
 title = {Spin-orbit torques associated with ferrimagnetic order in {Pt/GdFeCo/MgO} layers},
 volume = {8},
 copyright = {2018 The Author(s)},
 issn = {2045-2322},
 url = {https://doi.org/10.1038/s41598-018-24480-2},
 doi = {10.1038/s41598-018-24480-2},
 abstract = {We investigate spin orbit torque (SOT) efficiencies and magnetic properties of Pt/GdFeCo/MgO multilayers by varying the thicknesses of GdFeCo and MgO layers. Our studies indicate that the ferrimagnetism in the GdFeCo alloy is considerably influenced by both thicknesses due to the diffusion of Gd atoms toward the MgO layer. Comparing to conventional Pt/ferromagnet/MgO structures, the Pt/GdFeCo/MgO exhibits a lower efficiency of SOTs associated with ferrimagnetic order and a similar magnitude of magnetic damping. The previous models that have been developed for rigid ferromagnets are inappropriate to analyze our experimental data, leading to an unphysical consequence of spin transmission larger than unity. Our results imply that the heavy-metal/ferrimagnet system is quite different from heavy-metal/ferromagnet systems in terms of magnetic dynamical modes, spin angular momentum transfer, and relaxation processes.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Sci. Rep.},
 month = apr,
 year = {2018},
 pages = {1--8},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{betto_zero-moment_2016,
 author = {Betto, Davide and Rode, Karsten and Thiyagarajah, Naganivetha and Lau, Yong-Chang and Borisov, Kiril and Atcheson, Gwenael and Žic, Mario and Archer, Thomas and Stamenov, Plamen and Coey, J.M.D.},
 title = {The zero-moment half metal: {How} could it change spin electronics?},
 volume = {6},
 
 url = {https://doi.org/10.1063/1.4943756},
 doi = {10.1063/1.4943756},
 abstract = {The Heusler compound Mn2RuxGa (MRG) may well be the first compensated half metal. Here, the structural, magnetic and transport properties of thin films of MRG are discussed. There is evidence of half-metallicity up to x = 0.7, and compensation of the two Mn sublattice moments is observed at specific compositions and temperatures, leading to a zero-moment half metal. There are potential benefits for using such films with perpendicular anisotropy for spin-torque magnetic tunnel junctions and oscillators, such as low critical current, high tunnel magnetoresistance ratio, insensitivity to external fields and resonance frequency in the THz range.},
 number = {5},
 urldate = {2019-11-20},
 journal = {AIP Adv.},
 month = may,
 year = {2016},
 pages = {055601},
 source = {Crossref},
 publisher = {AIP Publishing},
 issn = {2158-3226},
}

@article{kurt_cubic_2014,
 author = {Kurt, H. and Rode, K. and Stamenov, P. and Venkatesan, M. and Lau, Y.-C. and Fonda, E. and Coey, J.M.D.},
 title = {{Cubic Mn2GaThin} Films: {Crossing} the Spin Gap with Ruthenium},
 volume = {112},
 
 url = {https://doi.org/10.1103/physrevlett.112.027201},
 doi = {10.1103/physrevlett.112.027201},
 abstract = {Cubic Mn2Ga films with the half-Heusler C1b structure are grown on V (001) epitaxial films. The phase is a soft ferrimagnet, with Curie temperature TC = 225 K and magnetization Ms=280 kA m-1, equivalent to 1.65$\mu$B per formula. Adding ruthenium leads to an increase of TC up to 550 K in cubic Mn2RuxGa films with x = 0.33 and a collapse of the net magnetization. The anomalous Hall effect changes sign at x = 0.5, where the sign of the magnetization changes and the magnetic easy direction flips from in plane to perpendicular to the film. The Mn2Ru0.5Ga compound with a valence electron count of 21 is identified as a zero-moment ferrimagnet with high spin polarization, which shows evidence of half-metallicity.},
 number = {2},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = jan,
 year = {2014},
 pages = {027201},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{gong_electrically_2018,
 author = {Gong, Shi-Jing and Gong, Cheng and Sun, Yu-Yun and Tong, Wen-Yi and Duan, Chun-Gang and Chu, Jun-Hao and Zhang, Xiang},
 title = {Electrically induced {2D} half-metallic antiferromagnets and spin field effect transistors},
 volume = {115},
 copyright = {{\copyright } 2018 . http://www.pnas.org/site/aboutpnas/licenses.xhtmlPublished under the PNAS license.},
 issn = {0027-8424, 1091-6490},
 url = {https://doi.org/10.1073/pnas.1715465115},
 doi = {10.1073/pnas.1715465115},
 abstract = {Engineering the electronic band structure of material systems enables the unprecedented exploration of new physical properties that are absent in natural or as-synthetic materials. Half metallicity, an intriguing physical property arising from the metallic nature of electrons with singular spin polarization and insulating for oppositely polarized electrons, holds a great potential for a 100\% spin-polarized current for high-efficiency spintronics. Conventionally synthesized thin films hardly sustain half metallicity inherited from their 3D counterparts. A fundamental challenge, in systems of reduced dimensions, is the almost inevitable spin-mixed edge or surface states in proximity to the Fermi level. Here, we predict electric field-induced half metallicity in bilayer A-type antiferromagnetic van der Waals crystals (i.e., intralayer ferromagnetism and interlayer antiferromagnetism), by employing density functional theory calculations on vanadium diselenide. Electric fields lift energy levels of the constituent layers in opposite directions, leading to the gradual closure of the gap of singular spin-polarized states and the opening of the gap of the others. We show that a vertical electrical field is a generic and effective way to achieve half metallicity in A-type antiferromagnetic bilayers and realize the spin field effect transistor. The electric field-induced half metallicity represents an appealing route to realize 2D half metals and opens opportunities for nanoscale highly efficient antiferromagnetic spintronics for information processing and storage.},
 number = {34},
 urldate = {2019-11-20},
 journal = {PNAS},
 month = aug,
 year = {2018},
 pmid = {30076226},
 keywords = {2D magnetism, 2D materials, antiferromagnetic spintronics, half metallicity, spin field effect transistor},
 pages = {8511-8516},
 source = {Crossref},
 publisher = {Proceedings of the National Academy of Sciences},
}

@article{van_leuken_half-metallic_1995,
 author = {van Leuken, H. and de Groot, R.A.},
 title = {Half-Metallic Antiferromagnets},
 volume = {74},
 url = {https://doi.org/10.1103/physrevlett.74.1171},
 doi = {10.1103/physrevlett.74.1171},
 abstract = {This Letter discusses the possibility of realizing half-metallic antiferromagnets, i.e., systems with 100\% spin polarization of the conduction electrons without showing a net magnetization. The predictions are based on electronic structure calculations using the local density approximation.},
 number = {7},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = feb,
 year = {1995},
 pages = {1171-1173},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{garello_symmetry_2013,
 author = {Garello, Kevin and Miron, Ioan Mihai and Avci, Can Onur and Freimuth, Frank and Mokrousov, Yuriy and Blügel, Stefan and Auffret, Stéphane and Boulle, Olivier and Gaudin, Gilles and Gambardella, Pietro},
 title = {Symmetry and magnitude of spin--orbit torques in ferromagnetic heterostructures},
 volume = {8},
 copyright = {2013 Nature Publishing Group},
 issn = {1748-3387, 1748-3395},
 url = {https://doi.org/10.1038/nnano.2013.145},
 doi = {10.1038/nnano.2013.145},
 abstract = {Spin{--}orbit torques in heavy metal/ferromagnetic layers have a complex dependence on the magnetization direction. This dependence can be exploited to increase the efficiency of spin{--}orbit torques.},
 number = {8},
 urldate = {2019-11-20},
 journal = {Nat. Nanotechnol.},
 month = jul,
 year = {2013},
 pages = {587-593},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@book{datta_electronic_1995,
 author = {Datta, Supriyo},
 place = {Cambridge},
 series = {Cambridge Studies in Semiconductor Physics and Microelectronic Engineering},
 title = {Electronic Transport in Mesoscopic Systems},
 doi = {10.1017/cbo9780511805776},
 publisher = {Cambridge University Press},
 year = {1995},
 collection = {Cambridge Studies in Semiconductor Physics and Microelectronic Engineering},
 source = {Crossref},
 url = {https://doi.org/10.1017/cbo9780511805776},
 isbn = {9780521416047, 9780521599436, 9780511805776},
 month = sep,
}

@article{ado_anisotropy_2019,
 author = {Ado, I.A. and Ostrovsky, P.M. and Titov, M.},
 title = {Anisotropy of spin-transfer torques and {Gilbert} damping induced by Rashba coupling},
 journal = {Phys. Rev. B},
 volume = {101},
 issue = {8},
 pages = {085405},
 numpages = {18},
 year = {2020},
 month = feb,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.101.085405},
 url = {https://doi.org/10.1103/physrevb.101.085405},
 number = {8},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
}

@article{ado_microscopic_2017,
 author = {Ado, I.A. and Tretiakov, Oleg A. and Titov, M.},
 title = {Microscopic theory of spin-orbit torques in two dimensions},
 volume = {95},
 url = {https://doi.org/10.1103/physrevb.95.094401},
 doi = {10.1103/physrevb.95.094401},
 abstract = {We formulate a general microscopic approach to spin-orbit torques in thin ferromagnet/heavy-metal bilayers in linear response to electric current or electric field. The microscopic theory we develop avoids the notion of spin currents and spin-Hall effect. Instead, the torques are directly related to a local spin polarization of conduction electrons, which is computed from generalized Kubo-St{\v r}eda formulas. A symmetry analysis provides a one-to-one correspondence between polarization susceptibility tensor components and different torque terms in the Landau-Lifshitz-Gilbert equation for magnetization dynamics. The spin-orbit torques arising from Rashba or Dresselhaus type of spin-orbit interaction are shown to have different symmetries. We analyze these spin-orbit torques microscopically for a generic electron model in the presence of an arbitrary smooth magnetic texture. For a model with spin-independent disorder we find a major cancellation of the torques. In this case the only remaining torque corresponds to the magnetization-independent Edelstein effect. Furthermore, our results are applied to analyze the dynamics of a skyrmion under the action of electric current.},
 number = {9},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = mar,
 year = {2017},
 pages = {094401},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{ezawa_photoinduced_2013,
 author = {Ezawa, Motohiko},
 title = {Photoinduced Topological Phase Transition and a Single {Dirac}-Cone State in Silicene},
 volume = {110},
 url = {https://doi.org/10.1103/physrevlett.110.026603},
 doi = {10.1103/physrevlett.110.026603},
 abstract = {Silicene (a monolayer of silicon atoms) is a two-dimensional topological insulator (TI) that undergoes a topological phase transition to a band insulator under external electric field Ez. We investigate a photoinduced topological phase transition from a TI to another TI by changing its topological class by irradiating circular polarized light at fixed Ez. The band structure is modified by photon dressing with a new dispersion, where the topological property is altered. By increasing the intensity of light at Ez=0, a photoinduced quantum Hall insulator is realized. Its edge modes are anisotropic chiral, in which the velocities of up and down spins are different. At Ez{\textgreater }Ecr with a certain critical field Ecr, a photoinduced spin-polarized quantum Hall insulator emerges. This is a new state of matter, possessing one Chern number and one-half spin-Chern numbers. We newly discover a single Dirac-cone state along a phase boundary. A distinctive hallmark of the state is that one of the two Dirac valleys is closed and the other open.},
 number = {2},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = jan,
 year = {2013},
 pages = {026603},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{qiao_microscopic_2012,
 author = {Qiao, Zhenhua and Jiang, Hua and Li, Xiao and Yao, Yugui and Niu, Qian},
 title = {Microscopic theory of quantum anomalous Hall effect in graphene},
 volume = {85},
 url = {https://doi.org/10.1103/physrevb.85.115439},
 doi = {10.1103/physrevb.85.115439},
 abstract = {We present a microscopic theory to give a physical picture of the formation of the quantum anomalous Hall (QAH) effect in magnetized graphene coupled with Rashba spin-orbit coupling. Based on a continuum model at valley K or K', we show that there exist two distinct physical origins of the QAH effect at two different limits. For large exchange field M, the quantization of Hall conductance in the absence of Landau-level quantization can be regarded as a summation of the topological charges carried by skyrmions from real-spin textures and merons from AB sublattice pseudospin textures, while for strong Rashba spin-orbit coupling $\lambda$R, the four-band low-energy model Hamiltonian is reduced to a two-band extended Haldane model, giving rise to a nonzero Chern number C=1 at either K or K'. In the presence of staggered AB sublattice potential U, a topological phase transition occurs at U=M from a QAH phase to a quantum valley Hall phase. We further find that the band gap responses at K and K' are different when $\lambda$R, M, and U are simultaneously considered. We also show that the QAH phase is robust against weak intrinsic spin-orbit coupling $\lambda$SO, and it transitions to a trivial phase when $\lambda$SO{\textgreater }(M2+$\lambda$R2+M)/2. Moreover, we use a tight-binding model to reproduce the ab initio method obtained band structures through doping magnetic atoms on 3{\texttimes }3 and 4{\texttimes }4 supercells of graphene, and explain the physical mechanisms of opening a nontrivial bulk gap to realize the QAH effect in different supercells of graphene.},
 number = {11},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = mar,
 year = {2012},
 pages = {115439},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{kane_$z_2$_2005,
 author = {Kane, C.L. and Mele, E.J.},
 title = {{Z2Topological} Order and the Quantum Spin Hall Effect},
 volume = {95},
 url = {https://doi.org/10.1103/physrevlett.95.146802},
 doi = {10.1103/physrevlett.95.146802},
 abstract = {The quantum spin Hall (QSH) phase is a time reversal invariant electronic state with a bulk electronic band gap that supports the transport of charge and spin in gapless edge states. We show that this phase is associated with a novel Z2 topological invariant, which distinguishes it from an ordinary insulator. The Z2 classification, which is defined for time reversal invariant Hamiltonians, is analogous to the Chern number classification of the quantum Hall effect. We establish the Z2 order of the QSH phase in the two band model of graphene and propose a generalization of the formalism applicable to multiband and interacting systems.},
 number = {14},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = sep,
 year = {2005},
 pages = {146802},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{groth_kwant:_2014,
 author = {Groth, Christoph W and Wimmer, Michael and Akhmerov, Anton R and Waintal, Xavier},
 title = {Kwant: {A} software package for quantum transport},
 volume = {16},
 issn = {1367-2630},
 
 url = {https://doi.org/10.1088/1367-2630/16/6/063065},
 doi = {10.1088/1367-2630/16/6/063065},
 abstract = {Kwant is a Python package for numerical quantum transport calculations. It aims to be a user-friendly, universal, and high-performance toolbox for the simulation of physical systems of any dimensionality and geometry that can be described by a tight-binding model. Kwant has been designed such that the natural concepts of the theory of quantum transport (lattices, symmetries, electrodes, orbital/spin/electron-hole degrees of freedom) are exposed in a simple and transparent way. Defining a new simulation setup is very similar to describing the corresponding mathematical model. Kwant offers direct support for calculations of transport properties (conductance, noise, scattering matrix), dispersion relations, modes, wave functions, various Green's functions, and out-of-equilibrium local quantities. Other computations involving tight-binding Hamiltonians can be implemented easily thanks to its extensible and modular nature. Kwant is free software available at http://kwant-project.org/.},
 number = {6},
 urldate = {2019-11-20},
 journal = {New J. Phys.},
 month = jun,
 year = {2014},
 pages = {063065},
 source = {Crossref},
 publisher = {IOP Publishing},
}

@article{tomasello_performance_2017,
 author = {Tomasello, R and Puliafito, V and Martinez, E and Manchon, A and Ricci, M and Carpentieri, M and Finocchio, G},
 title = {Performance of synthetic antiferromagnetic racetrack memory: {Domain} wall versus skyrmion},
 volume = {50},
 issn = {0022-3727, 1361-6463},
 
 url = {https://doi.org/10.1088/1361-6463/aa7a98},
 doi = {10.1088/1361-6463/aa7a98},
 number = {32},
 urldate = {2019-11-20},
 journal = {J. Phys. D: Appl. Phys.},
 month = jul,
 year = {2017},
 pages = {325302},
 source = {Crossref},
 publisher = {IOP Publishing},
}

@article{akosa_theory_2018,
 author = {Akosa, C.A. and Tretiakov, O.A. and Tatara, G. and Manchon, A.},
 title = {Theory of the Topological Spin Hall Effect in Antiferromagnetic Skyrmions: {Impact} on Current-Induced Motion},
 volume = {121},
 
 url = {https://doi.org/10.1103/physrevlett.121.097204},
 doi = {10.1103/physrevlett.121.097204},
 abstract = {We demonstrate that the nontrivial magnetic texture of antiferromagnetic Skyrmions (AFM Sks) promotes a nonvanishing topological spin Hall effect (TSHE) on the flowing electrons. This effect results in a substantial enhancement of the nonadiabatic torque and, hence, improves the Skyrmion mobility. This nonadiabatic torque increases when decreasing the Skyrmion size, and, therefore, scaling down results in a much higher torque efficiency. In clean AFM Sks, we find a significant boost of the TSHE close to the van Hove singularity. Interestingly, this effect is enhanced away from the band gap in the presence of nonmagnetic interstitial defects. Furthermore, unlike their ferromagnetic counterpart, the TSHE in AFM Sks increases with an increase in the disorder strength, thus opening promising avenues for materials engineering of this effect.},
 number = {9},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = aug,
 year = {2018},
 pages = {097204},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{shiino_antiferromagnetic_2016,
 author = {Shiino, Takayuki and Oh, Se-Hyeok and Haney, Paul M. and Lee, Seo-Won and Go, Gyungchoon and Park, Byong-Guk and Lee, Kyung-Jin},
 title = {Antiferromagnetic Domain Wall Motion Driven by Spin-Orbit Torques},
 volume = {117},
 url = {https://doi.org/10.1103/physrevlett.117.087203},
 doi = {10.1103/physrevlett.117.087203},
 abstract = {We theoretically investigate the dynamics of antiferromagnetic domain walls driven by spin-orbit torques in antiferromagnet{--}heavy-metal bilayers. We show that spin-orbit torques drive antiferromagnetic domain walls much faster than ferromagnetic domain walls. As the domain wall velocity approaches the maximum spin-wave group velocity, the domain wall undergoes Lorentz contraction and emits spin waves in the terahertz frequency range. The interplay between spin-orbit torques and the relativistic dynamics of antiferromagnetic domain walls leads to the efficient manipulation of antiferromagnetic spin textures and paves the way for the generation of high frequency signals from antiferromagnets.},
 number = {8},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = aug,
 year = {2016},
 pages = {087203},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{zhang_antiferromagnetic_2016,
 author = {Zhang, Xichao and Zhou, Yan and Ezawa, Motohiko},
 title = {Antiferromagnetic Skyrmion: {Stability,} Creation and Manipulation},
 volume = {6},
 copyright = {2016 The Author(s)},
 issn = {2045-2322},
 
 url = {https://doi.org/10.1038/srep24795},
 doi = {10.1038/srep24795},
 abstract = {Magnetic skyrmions are particle-like topological excitations in ferromagnets, which have the topo-logical number Q = {$\pm$} 1 and hence show the skyrmion Hall effect (SkHE) due to the Magnus force effect originating from the topology. Here, we propose the counterpart of the magnetic skyrmion in the antiferromagnetic (AFM) system, that is, the AFM skyrmion, which is topologically protected but without showing the SkHE. Two approaches for creating the AFM skyrmion have been described based on micromagnetic lattice simulations: (i) by injecting a vertical spin-polarized current to a nanodisk with the AFM ground state; (ii) by converting an AFM domain-wall pair in a nanowire junction. It is demonstrated that the AFM skyrmion, driven by the spin-polarized current, can move straightly over long distance, benefiting from the absence of the SkHE. Our results will open a new strategy on designing the novel spintronic devices based on AFM materials.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Sci. Rep.},
 month = apr,
 year = {2016},
 pages = {1--8},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{barker_static_2016,
 author = {Barker, Joseph and Tretiakov, Oleg A.},
 title = {Static and Dynamical Properties of Antiferromagnetic Skyrmions in the Presence of Applied Current and Temperature},
 volume = {116},
 url = {https://doi.org/10.1103/physrevlett.116.147203},
 doi = {10.1103/physrevlett.116.147203},
 abstract = {Skyrmions are topologically protected entities in magnetic materials which have the potential to be used in spintronics for information storage and processing. However, Skyrmions in ferromagnets have some intrinsic difficulties which must be overcome to use them for spintronic applications, such as the inability to move straight along current. We show that Skyrmions can also be stabilized and manipulated in antiferromagnetic materials. An antiferromagnetic Skyrmion is a compound topological object with a similar but of opposite sign spin texture on each sublattice, which, e.g., results in a complete cancellation of the Magnus force. We find that the composite nature of antiferromagnetic Skyrmions gives rise to different dynamical behavior due to both an applied current and temperature effects.},
 number = {14},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = apr,
 year = {2016},
 pages = {147203},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{hals_phenomenology_2011,
 author = {Hals, Kjetil M.D. and Tserkovnyak, Yaroslav and Brataas, Arne},
 title = {Phenomenology of Current-Induced Dynamics in Antiferromagnets},
 volume = {106},
 url = {https://doi.org/10.1103/physrevlett.106.107206},
 doi = {10.1103/physrevlett.106.107206},
 abstract = {We derive a phenomenological theory of current-induced staggered magnetization dynamics in antiferromagnets. The theory captures the reactive and dissipative current-induced torques and the conventional effects of magnetic fields and damping. A Walker ansatz describes the dc current-induced domain-wall motion when there is no dissipation. If magnetic damping and dissipative torques are included, the Walker ansatz remains robust when the domain wall moves slowly. As in ferromagnets, the domain-wall velocity is proportional to the ratio between the dissipative torque and the magnetization damping. In addition, a current-driven antiferromagnetic domain wall acquires a net magnetic moment.},
 number = {10},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = mar,
 year = {2011},
 pages = {107206},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{watanabe_symmetry_2018,
 author = {Watanabe, Hikaru and Yanase, Youichi},
 title = {Symmetry analysis of current-induced switching of antiferromagnets},
 volume = {98},
 url = {https://doi.org/10.1103/physrevb.98.220412},
 doi = {10.1103/physrevb.98.220412},
 abstract = {Antiferromagnets are robust to external electric and magnetic fields, and hence are seemingly uncontrollable. Recent studies, however, realized the electrical manipulations of antiferromagnets by virtue of the antiferromagnetic Edelstein effect. We present a general symmetry analysis of electrically switchable antiferromagnets based on group-theoretical approaches. Furthermore, we identify a direct relation between switchable antiferromagnets and the ferrotoroidic order. The concept of ferrotoroidic order clarifies the unidirectional nature of switchable antiferromagnets and provides a criterion for the controllability of antiferromagnets. The scheme paves a way for perfect writing and reading of switchable antiferromagnets.},
 number = {22},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = dec,
 year = {2018},
 pages = {220412},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{ghosh_nonequilibrium_2019,
 author = {Ghosh, S. and Manchon, A.},
 title = {Nonequilibrium spin density and spin-orbit torque in a three-dimensional topological insulator/antiferromagnet heterostructure},
 volume = {100},
 url = {https://doi.org/10.1103/physrevb.100.014412},
 doi = {10.1103/physrevb.100.014412},
 abstract = {We study the behavior of nonequilibrium spin density and spin-orbit torque in a topological insulator/antiferromagnet heterostructure. Unlike ferromagnetic heterostructures where the Dirac cone is gapped due to time-reversal symmetry breaking, here the Dirac cone is preserved. We demonstrate the existence of a staggered spin density corresponding to a dampinglike torque which is quite robust against scalar impurities when the transport energy is such that the transport is confined to the topological insulator surface. We show the contribution to the nonequilibrium spin density due to both surface and bulk topological insulator bands. Finally, we show that the torques in topological insulator/antiferromagnet heterostructures exhibit an angular dependence that is consistent with the standard spin-orbit torque obtained in Rashba system with some additional structure arising from the interfacial coupling.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = jul,
 year = {2019},
 pages = {014412},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{manchon_spin_2017,
 author = {Manchon, Aurelien},
 title = {Spin diffusion and torques in disordered antiferromagnets},
 volume = {29},
 issn = {0953-8984, 1361-648X},
 url = {https://doi.org/10.1088/1361-648x/aa521d},
 doi = {10.1088/1361-648x/aa521d},
 number = {10},
 urldate = {2019-11-20},
 journal = {J. Phys.: Condens. Matter},
 month = feb,
 year = {2017},
 pages = {104002},
 source = {Crossref},
 publisher = {IOP Publishing},
}

@article{khymyn_antiferromagnetic_2017,
 author = {Khymyn, Roman and Lisenkov, Ivan and Tiberkevich, Vasyl and Ivanov, Boris A. and Slavin, Andrei},
 title = {Antiferromagnetic {THz}-frequency {Josephson}-like Oscillator Driven by Spin Current},
 volume = {7},
 copyright = {2017 The Author(s)},
 issn = {2045-2322},
 url = {https://doi.org/10.1038/srep43705},
 doi = {10.1038/srep43705},
 abstract = {The development of compact and tunable room temperature sources of coherent THz-frequency signals would open a way for numerous new applications. The existing approaches to THz-frequency generation based on superconductor Josephson junctions (JJ), free electron lasers, and quantum cascades require cryogenic temperatures or/and complex setups, preventing the miniaturization and wide use of these devices. We demonstrate theoretically that a bi-layer of a heavy metal (Pt) and a bi-axial antiferromagnetic (AFM) dielectric (NiO) can be a source of a coherent THz signal. A spin-current flowing from a DC-current-driven Pt layer and polarized along the hard AFM anisotropy axis excites a non-uniform in time precession of magnetizations sublattices in the AFM, due to the presence of a weak easy-plane AFM anisotropy. The frequency of the AFM oscillations varies in the range of 0.1{--}2.0 THz with the driving current in the Pt layer from 108 A/cm2 to 109 A/cm2. The THz-frequency signal from the AFM with the amplitude exceeding 1 V/cm is picked up by the inverse spin-Hall effect in Pt. The operation of a room-temperature AFM THz-frequency oscillator is similar to that of a cryogenic JJ oscillator, with the energy of the easy-plane magnetic anisotropy playing the role of the Josephson energy.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Sci. Rep.},
 month = mar,
 year = {2017},
 pages = {1--10},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{cheng_terahertz_2016,
 author = {Cheng, Ran and Xiao, Di and Brataas, Arne},
 title = {Terahertz Antiferromagnetic Spin Hall Nano-Oscillator},
 volume = {116},
 url = {https://doi.org/10.1103/physrevlett.116.207603},
 doi = {10.1103/physrevlett.116.207603},
 abstract = {We consider the current-induced dynamics of insulating antiferromagnets in a spin Hall geometry. Sufficiently large in-plane currents perpendicular to the N{\'e}el order trigger spontaneous oscillations at frequencies between the acoustic and the optical eigenmodes. The direction of the driving current determines the chirality of the excitation. When the current exceeds a threshold, the combined effect of spin pumping and current-induced torques introduces a dynamic feedback that sustains steady-state oscillations with amplitudes controllable via the applied current. The ac voltage output is calculated numerically as a function of the dc current input for different feedback strengths. Our findings open a route towards terahertz antiferromagnetic spin-torque oscillators.},
 number = {20},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = may,
 year = {2016},
 pages = {207603},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{fjaerbu_electrically_2017,
 author = {Fjærbu, Eirik Løhaugen and Rohling, Niklas and Brataas, Arne},
 title = {Electrically driven {Bose}-{Einstein} condensation of magnons in antiferromagnets},
 volume = {95},
 url = {https://doi.org/10.1103/physrevb.95.144408},
 doi = {10.1103/physrevb.95.144408},
 abstract = {We explore routes to realize electrically driven Bose-Einstein condensation of magnons in insulating antiferromagnets. Even in insulating antiferromagnets, the localized spins can strongly couple to itinerant spins in adjacent metals via spin-transfer torque and spin pumping. We describe the formation of steady-state magnon condensates controlled by a spin accumulation polarized along the staggered field in an adjacent normal metal. Two types of magnons, which carry opposite magnetic moments, exist in antiferromagnets. Consequently, and in contrast to ferromagnets, Bose-Einstein condensation can occur for either sign of the spin accumulation. This condensation may occur even at room temperature when the interaction with the normal metal is fast compared to the relaxation processes within the antiferromagnet. In antiferromagnets, the operating frequencies of the condensate are orders of magnitude higher than in ferromagnets.},
 number = {14},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = apr,
 year = {2017},
 pages = {144408},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{zelezny_spin-orbit_2017,
 author = {Železný, J. and Gao, H. and Manchon, Aurélien and Freimuth, Frank and Mokrousov, Yuriy and Zemen, J. and Mašek, J. and Sinova, Jairo and Jungwirth, T.},
 title = {Spin-orbit torques in locally and globally noncentrosymmetric crystals: {Antiferromagnets} and ferromagnets},
 volume = {95},
 
 url = {https://doi.org/10.1103/physrevb.95.014403},
 doi = {10.1103/physrevb.95.014403},
 abstract = {One of the main obstacles that prevents practical applications of antiferromagnets is the difficulty of manipulating the magnetic order parameter. Recently, following the theoretical prediction [J. {\v Z}elezn{\'y} others, Phys. Rev. Lett. 113, 157201 (2014)], the electrical switching of magnetic moments in an antiferromagnet was demonstrated [P. Wadley others, Science 351, 587 (2016)]. The switching is due to the so-called spin-orbit torque, which has been extensively studied in ferromagnets. In this phenomena a nonequilibrium spin-polarization exchange coupled to the ordered local moments is induced by current, hence exerting a torque on the order parameter. Here we give a general systematic analysis of the symmetry of the spin-orbit torque in locally and globally noncentrosymmetric crystals. We study when the symmetry allows for a nonzero torque, when is the torque effective, and its dependence on the applied current direction and orientation of magnetic moments. For comparison, we consider both antiferromagnetic and ferromagnetic orders. In two representative model crystals we perform microscopic calculations of the spin-orbit torque to illustrate its symmetry properties and to highlight conditions under which the spin-orbit torque can be efficient for manipulating antiferromagnetic moments.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = jan,
 year = {2017},
 pages = {014403},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{tshitoyan_electrical_2015,
 author = {Tshitoyan, V. and Ciccarelli, C. and Mihai, A.P. and Ali, M. and Irvine, A.C. and Moore, T.A. and Jungwirth, T. and Ferguson, A.J.},
 title = {Electrical manipulation of ferromagnetic {NiFe} by antiferromagnetic {IrMn}},
 volume = {92},
 url = {https://doi.org/10.1103/physrevb.92.214406},
 doi = {10.1103/physrevb.92.214406},
 abstract = {We demonstrate that an antiferromagnet can be employed for a highly efficient electrical manipulation of a ferromagnet. In our study, we use an electrical detection technique of the ferromagnetic resonance driven by an in-plane ac current in a NiFe/IrMn bilayer. At room temperature, we observe antidampinglike spin torque acting on the NiFe ferromagnet, generated by an in-plane current driven through the IrMn antiferromagnet. A large enhancement of the torque, characterized by an effective spin-Hall angle exceeding most heavy transition metals, correlates with the presence of the exchange-bias field at the NiFe/IrMn interface. It highlights that, in addition to the strong spin-orbit coupling, the antiferromagnetic order in IrMn governs the observed phenomenon.},
 number = {21},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = dec,
 year = {2015},
 pages = {214406},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{pandey_doping_2017,
 author = {Pandey, S.K. and Mahadevan, Priya and Sarma, D.D.},
 title = {Doping an antiferromagnetic insulator: {A} route to an antiferromagnetic metallic phase},
 volume = {117},
 issn = {0295-5075, 1286-4854},
 
 url = {https://doi.org/10.1209/0295-5075/117/57003},
 doi = {10.1209/0295-5075/117/57003},
 number = {5},
 urldate = {2019-11-20},
 journal = {EPL},
 month = mar,
 year = {2017},
 pages = {57003},
 source = {Crossref},
 publisher = {IOP Publishing},
}

@article{bhattacharjee_neel_2018,
 author = {Bhattacharjee, N. and Sapozhnik, A.A. and Bodnar, S.Yu. and Grigorev, V.Yu. and Agustsson, S.Y. and Cao, J. and Dominko, D. and Obergfell, M. and Gomonay, O. and Sinova, J. and Kläui, M. and Elmers, H.-J. and Jourdan, M. and Demsar, J.},
 title = {N\'eel Spin-Orbit Torque Driven Antiferromagnetic Resonance in {Mn2Au} Probed by Time-Domain {THz} Spectroscopy},
 volume = {120},
 url = {https://doi.org/10.1103/physrevlett.120.237201},
 doi = {10.1103/physrevlett.120.237201},
 abstract = {We observe the excitation of collective modes in the terahertz (THz) range driven by the recently discovered N{\'e}el spin-orbit torques (NSOTs) in the metallic antiferromagnet Mn2Au. Temperature-dependent THz spectroscopy reveals a strong absorption mode centered near 1 THz, which upon heating from 4 to 450 K softens and loses intensity. A comparison with the estimated eigenmode frequencies implies that the observed mode is an in-plane antiferromagnetic resonance (AFMR). The AFMR absorption strength exceeds those found in antiferromagnetic insulators, driven by the magnetic field of the THz radiation, by 3 orders of magnitude. Based on this and the agreement with our theory modeling, we infer that the driving mechanism for the observed mode is the current-induced NSOT. Here the electric field component of the THz pulse drives an ac current in the metal, which subsequently drives the AFMR. This electric manipulation of the N{\'e}el order parameter at high frequencies makes Mn2Au a prime candidate for antiferromagnetic ultrafast memory applications.},
 number = {23},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = jun,
 year = {2018},
 pages = {237201},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{barthem_revealing_2013,
 author = {Barthem, V.M.T.S. and Colin, C.V. and Mayaffre, H. and Julien, M.-H. and Givord, D.},
 title = {Revealing the properties of {Mn2Au} for antiferromagnetic spintronics},
 volume = {4},
 copyright = {2013 Nature Publishing Group, a division of Macmillan Publishers Limited. All Rights Reserved.},
 issn = {2041-1723},
 url = {https://doi.org/10.1038/ncomms3892},
 doi = {10.1038/ncomms3892},
 abstract = {Few of the known antiferromagnetic materials are suitable for use in spintronic devices. Here, the authors show that Mn2Au, which was believed to be paramagnetic, is an antiferromagnet, combining high N{\'e}el temperature and in-plane anisotropy, thus demonstrating its potential for antiferromagnetic spintronics.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Nat. Commun.},
 month = dec,
 year = {2013},
 pages = {1--7},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{saidl_optical_2017,
 author = {Saidl, V. and Němec, P. and Wadley, P. and Hills, V. and Campion, R.P. and Novák, V. and Edmonds, K.W. and Maccherozzi, F. and Dhesi, S.S. and Gallagher, B.L. and Trojánek, F. and Kuneš, J. and Železný, J. and Malý, P. and Jungwirth, T.},
 title = {Optical determination of the N\'eel vector in a {CuMnAs} thin-film antiferromagnet},
 volume = {11},
 copyright = {2016 Nature Publishing Group},
 issn = {1749-4885, 1749-4893},
 url = {https://doi.org/10.1038/nphoton.2016.255},
 doi = {10.1038/nphoton.2016.255},
 abstract = {Due to their nature antiferromagnets are difficult to probe with conventional magnetometers. The N{\'e}el vector of a practically important antiferromagnet, CuMnAs, has now been determined by a femtosecond pump{--}probe magneto-optical experiment.},
 number = {2},
 urldate = {2019-11-20},
 journal = {Nat. Photon.},
 month = jan,
 year = {2017},
 pages = {91-96},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{bodnar_writing_2018,
 author = {Bodnar, S.Yu. and Šmejkal, L. and Turek, I. and Jungwirth, T. and Gomonay, O. and Sinova, J. and Sapozhnik, A.A. and Elmers, H.-J. and Kläui, M. and Jourdan, M.},
 title = {Writing and reading antiferromagnetic {Mn2Au} by N\'eel spin-orbit torques and large anisotropic magnetoresistance},
 volume = {9},
 copyright = {2018 The Author(s)},
 issn = {2041-1723},
 url = {https://doi.org/10.1038/s41467-017-02780-x},
 doi = {10.1038/s41467-017-02780-x},
 abstract = {The zero net moment of antiferromagnets makes them insensitive to magnetic fields and enables ultrafast dynamics promising for novel spintronics. Here the authors achieved pulse current induced N{\'e}el vector switching in Mn2Au(001) epitaxial thin films, which is associated with a large magnetoresistive effect allowing simple read-out.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Nat. Commun.},
 month = jan,
 year = {2018},
 pages = {1--7},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{zhou_large_2019,
 author = {Zhou, Jing and Wang, Xiao and Liu, Yaohua and Yu, Jihang and Fu, Huixia and Liu, Liang and Chen, Shaohai and Deng, Jinyu and Lin, Weinan and Shu, Xinyu and Yoong, Herng Yau and Hong, Tao and Matsuda, Masaaki and Yang, Ping and Adams, Stefan and Yan, Binghai and Han, Xiufeng and Chen, Jingsheng},
 title = {Large spin-orbit torque efficiency enhanced by magnetic structure of collinear antiferromagnet {IrMn}},
 volume = {5},
 copyright = {Copyright {\copyright } 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).. This is an open-access article distributed under the terms of the Creative Commons Attribution-NonCommercial license, which permits use, distribution, and reproduction in any medium, so long as the resultant use is not for commercial advantage and provided the original work is properly cited.},
 issn = {2375-2548},
 url = {https://doi.org/10.1126/sciadv.aau6696},
 doi = {10.1126/sciadv.aau6696},
 abstract = {Spin-orbit torque (SOT) offers promising approaches to developing energy-efficient memory devices by electric switching of magnetization. Compared to other SOT materials, metallic antiferromagnet (AFM) potentially allows the control of SOT through its magnetic structure. Here, combining the results from neutron diffraction and spin-torque ferromagnetic resonance experiments, we show that the magnetic structure of epitaxially grown L10-IrMn (a collinear AFM) is distinct from the widely presumed bulk one. It consists of twin domains, with the spin axes orienting toward [111] and [-111], respectively. This unconventional magnetic structure is responsible for much larger SOT efficiencies up to 0.60 {$\pm$} 0.04, compared to 0.083 {$\pm$} 0.002 for the polycrystalline IrMn. Furthermore, we reveal that this magnetic structure induces a large isotropic bulk contribution and a comparable anisotropic interfacial contribution to the SOT efficiency. Our findings shed light on the critical roles of bulk and interfacial antiferromagnetism to SOT generated by metallic AFM. Collinear IrMn offers new opportunities for future magnetic memory design as it can be an effective source of spin-orbit torque. Collinear IrMn offers new opportunities for future magnetic memory design as it can be an effective source of spin-orbit torque.},
 number = {5},
 urldate = {2019-11-20},
 journal = {Sci. Adv.},
 month = may,
 year = {2019},
 pages = {eaau6696},
 source = {Crossref},
 publisher = {American Association for the Advancement of Science (AAAS)},
}

@article{zhou_fieldlike_2019,
 author = {Zhou, X.F. and Chen, X.Z. and Zhang, J. and Li, F. and Shi, G.Y. and Sun, Y.M. and Saleem, M.S. and You, Y.F. and Pan, F. and Song, C.},
 title = {From Fieldlike Torque to Antidamping Torque in Antiferromagnetic {Mn2Au}},
 volume = {11},
 url = {https://doi.org/10.1103/physrevapplied.11.054030},
 doi = {10.1103/physrevapplied.11.054030},
 abstract = {Efficient electrical switching of antiferromagnets is at the center of their application in high-density and ultrafast nonvolatile memories. Antiferromagnetic (AFM) Mn2Au with opposite-spin sublattices is a unique metallic material in which the Edelstein effect can induce fieldlike torque switching of the AFM moments. However, the antidamping-torque-induced AFM moment switching remains to be proved in metallic AFM materials. Here, we demonstrate current-induced AFM moment switching in both a (103)-oriented Mn2Au single layer and Mn2Au/Pt heterojunction, detected by the spin Hall magnetoresistance and anisotropic magnetoresistance at room temperature. In (103)-oriented Mn2Au, fieldlike torque induces the alignment of AFM moments perpendicular to the writing current direction. Once the (103)-oriented Mn2Au film is covered by a thin Pt layer, the antidamping torque induced by the spin current from the Pt layer drives the AFM moments of Mn2Au switching toward the direction parallel to the writing current, which is in contrast to the case without Pt. The simultaneous realization of fieldlike torque and antidamping torque in metallic Mn2Au makes it a promising candidate in AFM spintronics.},
 number = {5},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Applied},
 month = may,
 year = {2019},
 pages = {054030},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2331-7019},
}

@article{chen_electric_2019,
 author = {Chen, Xianzhe and Zhou, Xiaofeng and Cheng, Ran and Song, Cheng and Zhang, Jia and Wu, Yichuan and Ba, You and Li, Haobo and Sun, Yiming and You, Yunfeng and Zhao, Yonggang and Pan, Feng},
 title = {Electric field control of N\'eel spin--orbit torque in an antiferromagnet},
 volume = {18},
 copyright = {2019 The Author(s), under exclusive licence to Springer Nature Limited},
 issn = {1476-1122, 1476-4660},
 url = {https://doi.org/10.1038/s41563-019-0424-2},
 doi = {10.1038/s41563-019-0424-2},
 abstract = {A ferroelectric material is used to switch the uniaxial magnetic anisotropy of an antiferromagnet, with implications for antiferromagnetic spintronics.},
 number = {9},
 urldate = {2019-11-20},
 journal = {Nat. Mater.},
 month = jul,
 year = {2019},
 pages = {931-935},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{li_manipulation_2019,
 author = {Li, Yucai and Edmonds, Kevin William and Liu, Xionghua and Zheng, Houzhi and Wang, Kaiyou},
 title = {Manipulation of Magnetization by Spin-Orbit Torque},
 volume = {2},
 issn = {2511-9044},
 url = {https://doi.org/10.1002/qute.201800052},
 doi = {10.1002/qute.201800052},
 abstract = {The control of magnetization by electric current is a rapidly developing area motivated by a strong synergy between breakthrough basic research discoveries and industrial applications in the fields of magnetic recording, magnetic field sensors, spintronics, and nonvolatile memories. In recent years, the discovery of spin{--}orbit torque has opened a spectrum of opportunities to manipulate the magnetization efficiently. This article presents a review of the historical background and recent literature focusing on spin{--}orbit torques (SOTs), highlighting the most exciting new scientific results and suggesting promising future research directions. It starts with an introduction and overview of the underlying physics of spin{--}orbit coupling effects in bulk and at interfaces, and then describes the use of SOTs to control ferromagnets and antiferromagnets. Finally, the prospects for the future development of spintronic devices based on SOTs are summarized.},
 number = {1-2},
 urldate = {2019-11-20},
 journal = {Adv. Quantum Technol.},
 year = {2018},
 keywords = {Dzyaloshinskii{--}Moriya interaction, Rashba effect, spin Hall effect, spin{--}orbit coupling, spin{--}orbit torques},
 pages = {1800052},
 source = {Crossref},
 publisher = {Wiley},
 month = oct,
}

@article{moriyama_spin-orbit-torque_2018,
 author = {Moriyama, Takahiro and Zhou, Weinan and Seki, Takeshi and Takanashi, Koki and Ono, Teruo},
 title = {Spin-Orbit-Torque Memory Operation of Synthetic Antiferromagnets},
 volume = {121},
 url = {https://doi.org/10.1103/physrevlett.121.167202},
 doi = {10.1103/physrevlett.121.167202},
 abstract = {In this Letter, we show the demonstration of a sequential antiferromagnetic memory operation with a spin-orbit-torque write, by the spin Hall effect, and a resistive read in the CoGd synthetic antiferromagnetic bits, in which we reveal the distinct differences in the spin-orbit-torque and field-induced switching mechanisms of the antiferromagnetic moment, or the N{\'e}el vector. In addition to the comprehensive spin torque memory operation, our thorough investigations also highlight the high immunity to a field disturbance as well as a memristive behavior of the antiferromagnetic bits.},
 number = {16},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = oct,
 year = {2018},
 pages = {167202},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{manchon_current-induced_2019,
 author = {Manchon, A. and Železný, J. and Miron, I.M. and Jungwirth, T. and Sinova, J. and Thiaville, A. and Garello, K. and Gambardella, P.},
 title = {Current-induced spin-orbit torques in ferromagnetic and antiferromagnetic systems},
 volume = {91},
 issn = {0034-6861, 1539-0756},
 url = {https://doi.org/10.1103/revmodphys.91.035004},
 doi = {10.1103/revmodphys.91.035004},
 abstract = {Spin-orbit coupling in inversion-asymmetric magnetic crystals and structures has emerged as a powerful tool to generate complex magnetic textures, interconvert charge and spin under applied current, and control magnetization dynamics. Current-induced spin-orbit torques mediate the transfer of angular momentum from the lattice to the spin system, leading to sustained magnetic oscillations or switching of ferromagnetic as well as antiferromagnetic structures. The manipulation of magnetic order, domain walls and skyrmions by spin-orbit torques provides evidence of the microscopic interactions between charge and spin in a variety of materials and opens novel strategies to design spintronic devices with potentially high impact in data storage, nonvolatile logic, and magnonic applications. This paper reviews recent progress in the field of spin-orbitronics, focusing on theoretical models, material properties, and experimental results obtained on bulk noncentrosymmetric conductors and multilayer heterostructures, including metals, semiconductors, and topological insulator systems. Relevant aspects for improving the understanding and optimizing the efficiency of nonequilibrium spin-orbit phenomena in future nanoscale devices are also discussed.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Rev. Mod. Phys.},
 month = sep,
 year = {2019},
 keywords = {Condensed Matter - Mesoscale and Nanoscale Physics},
 pages = {035004},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
}

@article{zhou_strong_2018,
 author = {Zhou, X.F. and Zhang, J. and Li, F. and Chen, X.Z. and Shi, G.Y. and Tan, Y.Z. and Gu, Y.D. and Saleem, M.S. and Wu, H.Q. and Pan, F. and Song, C.},
 title = {Strong Orientation-Dependent Spin-Orbit Torque in Thin Films of the Antiferromagnet {Mn2Au}},
 volume = {9},
 url = {https://doi.org/10.1103/physrevapplied.9.054028},
 doi = {10.1103/physrevapplied.9.054028},
 abstract = {Antiferromagnets with zero net magnetic moment, strong anti-interference, and ultrafast switching speed are potentially competitive in high-density information storage. The body-centered tetragonal antiferromagnet Mn2Au with opposite-spin sublattices is a unique metallic material for N{\'e}el-order spin-orbit-torque (SOT) switching. We investigate the SOT switching in quasiepitaxial (103), (101) and (204) Mn2Au films prepared by a simple magnetron sputtering method. We demonstrate current-induced antiferromagnetic moment switching in all of the prepared Mn2Au films by using a short current pulse at room temperature, whereas differently oriented films exhibit distinguished switching characters. A direction-independent reversible switching is attained in Mn2Au (103) films due to negligible magnetocrystalline anisotropy energy, while for Mn2Au (101) and (204) films, the switching is invertible with the current applied along the in-plane easy axis and its vertical axis, but it becomes attenuated seriously during initial switching circles when the current is applied along the hard axis because of the existence of magnetocrystalline anisotropy energy. Besides the fundamental significance, the strong orientation-dependent SOT switching, which is not realized, irrespective of ferromagnet and antiferromagnet, provides versatility for spintronics.},
 number = {5},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Applied},
 month = may,
 year = {2018},
 pages = {054028},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2331-7019},
}

@article{zelezny_spin_2018,
 author = {Železný, J. and Wadley, P. and Olejník, K. and Hoffmann, A. and Ohno, H.},
 title = {Spin transport and spin torque in antiferromagnetic devices},
 volume = {14},
 copyright = {2018 The Publisher},
 issn = {1745-2473, 1745-2481},
 url = {https://doi.org/10.1038/s41567-018-0062-7},
 doi = {10.1038/s41567-018-0062-7},
 abstract = {As part of a focus on antiferromagnetic spintronics, this Review considers the role of spin transport and spin torque in potential antiferromagnetic memory devices.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Nat. Phys.},
 month = mar,
 year = {2018},
 pages = {220-228},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{smejkal_electric_2017,
 author = {Šmejkal, L. and Železný, J. and Sinova, J. and Jungwirth, T.},
 title = {Electric Control of {Dirac} Quasiparticles by Spin-Orbit Torque in an Antiferromagnet},
 volume = {118},
 url = {https://doi.org/10.1103/physrevlett.118.106402},
 doi = {10.1103/physrevlett.118.106402},
 abstract = {Spin orbitronics and Dirac quasiparticles are two fields of condensed matter physics initiated independently about a decade ago. Here we predict that Dirac quasiparticles can be controlled by the spin-orbit torque reorientation of the N{\'e}el vector in an antiferromagnet. Using CuMnAs as an example, we formulate symmetry criteria allowing for the coexistence of topological Dirac quasiparticles and N{\'e}el spin-orbit torques. We identify the nonsymmorphic crystal symmetry protection of Dirac band crossings whose on and off switching is mediated by the N{\'e}el vector reorientation. We predict that this concept verified by minimal model and density functional calculations in the CuMnAs semimetal antiferromagnet can lead to a topological metal-insulator transition driven by the N{\'e}el vector and to the topological anisotropic magnetoresistance.},
 number = {10},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = mar,
 year = {2017},
 pages = {106402},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{ghosh_spin-orbit_2017,
 author = {Ghosh, S. and Manchon, A.},
 title = {Spin-orbit torque in two-dimensional antiferromagnetic topological insulators},
 volume = {95},
 url = {https://doi.org/10.1103/physrevb.95.035422},
 doi = {10.1103/physrevb.95.035422},
 abstract = {We investigate spin transport in two-dimensional ferromagnetic (FTI) and antiferromagnetic (AFTI) topological insulators. In the presence of an in-plane magnetization AFTI supports zero energy modes, which enables topologically protected edge conduction at low energy. We address the nature of current-driven spin torque in these structures and study the impact of spin-independent disorder. Interestingly, upon strong disorder the spin torque develops an antidamping component (i.e., even upon magnetization reversal) along the edges, which could enable current-driven manipulation of the antiferromagnetic order parameter. This antidamping torque decreases when increasing the system size and when the system enters the trivial insulator regime.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = jan,
 year = {2017},
 pages = {035422},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{freimuth_spin-orbit_2014,
 author = {Freimuth, Frank and Blügel, Stefan and Mokrousov, Yuriy},
 title = {Spin-orbit torques in {Co/Pt(111)} and {Mn/W(001)} magnetic bilayers from first principles},
 volume = {90},
 url = {https://doi.org/10.1103/physrevb.90.174423},
 doi = {10.1103/physrevb.90.174423},
 abstract = {An applied electric current through a space-inversion asymmetric magnet induces spin-orbit torques (SOTs) on the magnetic moments, which holds much promise for future memory devices. We discuss general Green's function expressions suitable to compute the linear-response SOT in disordered ferromagnets. The SOT can be decomposed into an even and an odd component with respect to magnetization reversal, where in the limit of vanishing disorder the even SOT is given by the constant Berry curvature of the occupied states, while the odd part exhibits a divergence with respect to disorder strength. Within this formalism, we perform first-principles density-functional theory calculations of the SOT in Co/Pt(111) and Mn/W(001) magnetic bilayers. We find the even and odd torque components to be of comparable magnitude. Moreover, the odd torque depends strongly on an additional capping layer, while the even torque is less sensitive. We show that the even torque is nearly entirely mediated by spin currents in contrast to the odd torque, which can contain an important contribution not due to spin transfer. Our results are in agreement with experiments, showing that our linear-response theory is well-suited for the description of SOTs in complex ferromagnets.},
 number = {17},
 urldate = {2019-11-20},
 journal = {Phys. Rev. B},
 month = nov,
 year = {2014},
 pages = {174423},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {1098-0121, 1550-235X},
}

@article{zelezny_relativistic_2014,
 author = {Železný, J. and Gao, H. and Výborný, K. and Zemen, J. and Mašek, J. and Manchon, Aurélien and Wunderlich, J. and Sinova, Jairo and Jungwirth, T.},
 title = {Relativistic N\'eel-Order Fields Induced by Electrical Current in Antiferromagnets},
 volume = {113},
 url = {https://doi.org/10.1103/physrevlett.113.157201},
 doi = {10.1103/physrevlett.113.157201},
 abstract = {We predict that a lateral electrical current in antiferromagnets can induce nonequilibrium N{\'e}el-order fields, i.e., fields whose sign alternates between the spin sublattices, which can trigger ultrafast spin-axis reorientation. Based on microscopic transport theory calculations we identify staggered current-induced fields analogous to the intraband and to the intrinsic interband spin-orbit fields previously reported in ferromagnets with a broken inversion-symmetry crystal. To illustrate their rich physics and utility, we consider bulk Mn2Au with the two spin sublattices forming inversion partners, and a 2D square-lattice antiferromagnet with broken structural inversion symmetry modeled by a Rashba spin-orbit coupling. We propose an antiferromagnetic memory device with electrical writing and reading.},
 number = {15},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = oct,
 year = {2014},
 pages = {157201},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{brataas_current-induced_2012,
 author = {Brataas, Arne and Kent, Andrew D. and Ohno, Hideo},
 title = {Current-induced torques in magnetic materials},
 volume = {11},
 copyright = {2012 Nature Publishing Group, a division of Macmillan Publishers Limited. All Rights Reserved.},
 issn = {1476-1122, 1476-4660},
 url = {https://doi.org/10.1038/nmat3311},
 doi = {10.1038/nmat3311},
 abstract = {Spin-transfer torque is the rotation that a spin-polarized current induces on the magnetization of the solid it flows through. The way in which currents generate torques in a wide variety of magnetic materials and structures is discussed in this Review, as well as recent state-of-the-art demonstrations of current-induced-torque devices that show great promise for enhancing the functionality of semiconductor devices.},
 number = {5},
 urldate = {2019-11-20},
 journal = {Nat. Mater.},
 month = apr,
 year = {2012},
 pages = {372-381},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{fina_electric_2017,
 author = {Fina, Ignasi and Marti, Xavier},
 title = {Electric control of antiferromagnets},
 volume = {53},
 issn = {0018-9464, 1941-0069},
 doi = {10.1109/tmag.2016.2606561},
 abstract = {In the past five years, most of the paradigmatic concepts employed in spintronics have been replicated substituting ferromagnets by antiferromagnets in the critical parts of the devices. The numerous research efforts directed to manipulate and probe the magnetic moments in antiferromagnets have been gradually established a new and independent field known as antiferromagnetic spintronics. In this paper, we focus on the electrical control and detection of antiferromagnetic moments at a constant temperature. We address separately the experimental results concerning insulating and metallic thin films as they correspond to voltage and electrical current controlled devices, respectively. First, we present results on the voltage control of antiferromagnetic order in insulating thin films. The experiments show that voltage pulses can switch the chirality of a modulated antiferromagnetic structure. Second, we describe the recent advances in metallic antiferromagnetic systems. We present results obtained with the first USB-operated portable device able to perform the nonvolatile electrical current-induced switching of an antiferromagnet combined with magnetoresistive readout at room temperature. We discuss on potential applications that can be realized using antiferromagnetic memory cells.},
 number = {2},
 journal = {IEEE Trans. Magn.},
 month = feb,
 year = {2016},
 keywords = {antiferromagnetic materials, antiferromagnetic memory cells, antiferromagnetic moments, Antiferromagnetism, antiferromagnets, devices, electric control, electric current control, electrical current controlled devices, insulating thin films, Magnetic domain walls, Magnetic domains, Magnetic fields, magnetoelectric, Magnetoelectric effects, magnetoelectronics, magnetoresistive devices, magnetoresistive readout, metallic antiferromagnetic systems, metallic thin films, modulated antiferromagnetic structure, Perpendicular magnetic anisotropy, spintronics, Switches, voltage control, voltage controlled devices},
 pages = {1-1},
 source = {Crossref},
 url = {https://doi.org/10.1109/tmag.2016.2606561},
 publisher = {Institute of Electrical and Electronics Engineers (IEEE)},
}

@article{olejnik_terahertz_2018,
 author = {Olejník, Kamil and Seifert, Tom and Kašpar, Zdeněk and Novák, Vít and Wadley, Peter and Campion, Richard P. and Baumgartner, Manuel and Gambardella, Pietro and Němec, Petr and Wunderlich, Joerg and Sinova, Jairo and Kužel, Petr and Müller, Melanie and Kampfrath, Tobias and Jungwirth, Tomas},
 title = {Terahertz electrical writing speed in an antiferromagnetic memory},
 volume = {4},
 copyright = {Copyright {\copyright } 2018 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).. This is an open-access article distributed under the terms of the Creative Commons Attribution-NonCommercial license, which permits use, distribution, and reproduction in any medium, so long as the resultant use is not for commercial advantage and provided the original work is properly cited.},
 issn = {2375-2548},
 url = {https://doi.org/10.1126/sciadv.aar3566},
 doi = {10.1126/sciadv.aar3566},
 abstract = {The speed of writing of state-of-the-art ferromagnetic memories is physically limited by an intrinsic gigahertz threshold. Recently, realization of memory devices based on antiferromagnets, in which spin directions periodically alternate from one atomic lattice site to the next has moved research in an alternative direction. We experimentally demonstrate at room temperature that the speed of reversible electrical writing in a memory device can be scaled up to terahertz using an antiferromagnet. A current-induced spin-torque mechanism is responsible for the switching in our memory devices throughout the 12-order-of-magnitude range of writing speeds from hertz to terahertz. Our work opens the path toward the development of memory-logic technology reaching the elusive terahertz band. We demonstrate terahertz electrical writing speed in an antiferromagnetic memory at an energy of the gigahertz speed writing. We demonstrate terahertz electrical writing speed in an antiferromagnetic memory at an energy of the gigahertz speed writing.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Sci. Adv.},
 month = mar,
 year = {2018},
 pages = {eaar3566},
 source = {Crossref},
 publisher = {American Association for the Advancement of Science (AAAS)},
}

@article{gomonay_high_2016,
 author = {Gomonay, O. and Jungwirth, T. and Sinova, J.},
 title = {High Antiferromagnetic Domain Wall Velocity Induced by N\'eel Spin-Orbit Torques},
 volume = {117},
 url = {https://doi.org/10.1103/physrevlett.117.017202},
 doi = {10.1103/physrevlett.117.017202},
 abstract = {We demonstrate the possibility to drive an antiferromagnetic domain wall at high velocities by fieldlike N{\'e}el spin-orbit torques. Such torques arise from current-induced local fields that alternate their orientation on each sublattice of the antiferromagnet and whose orientation depends primarily on the current direction, giving them their fieldlike character. The domain wall velocities that can be achieved by this mechanism are 2 orders of magnitude greater than the ones in ferromagnets. This arises from the efficiency of the staggered spin-orbit fields to couple to the order parameter and from the exchange-enhanced phenomena in antiferromagnetic texture dynamics, which leads to a low domain wall effective mass and the absence of a Walker breakdown limit. In addition, because of its nature, the staggered spin-orbit field can lift the degeneracy between two 180{$^\circ$} rotated states in a collinear antiferromagnet, and it provides a force that can move such walls and control the switching of the states.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Phys. Rev. Lett.},
 month = jun,
 year = {2016},
 pages = {017202},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0031-9007, 1079-7114},
}

@article{jungfleisch_perspectives_2018,
 author = {Jungfleisch, Matthias B. and Zhang, Wei and Hoffmann, Axel},
 title = {Perspectives of antiferromagnetic spintronics},
 volume = {382},
 issn = {0375-9601},
 url = {https://doi.org/10.1016/j.physleta.2018.01.008},
 doi = {10.1016/j.physleta.2018.01.008},
 abstract = {Antiferromagnets are promising for future spintronic applications owing to their advantageous properties: They are magnetically ordered, but neighboring magnetic moments point in opposite directions, which results in zero net magnetization. This means antiferromagnets produce no stray fields and are insensitive to external magnetic field perturbations. Furthermore, they show intrinsic high frequency dynamics, exhibit considerable spin{--}orbit and magneto-transport effects. Over the past decade, it has been realized that antiferromagnets have more to offer than just being utilized as passive components in exchange bias applications. This development resulted in a paradigm shift, which opens the pathway to novel concepts using antiferromagnets for spin-based technologies and applications. This article gives a broad perspective on antiferromagnetic spintronics. In particular, the manipulation and detection of antiferromagnetic states by spintronics effects, as well as spin transport and dynamics in antiferromagnetic materials will be discussed. We will also outline current challenges and future research directions in this emerging field.},
 number = {13},
 urldate = {2019-11-20},
 journal = {Phys. Lett. A},
 month = apr,
 year = {2018},
 keywords = {Antiferromagnets, Magnons, Spin dynamics, Spin Hall effect, Spintronics},
 pages = {865-871},
 source = {Crossref},
 publisher = {Elsevier BV},
}

@article{jungwirth_multiple_2018,
 author = {Jungwirth, T. and Sinova, J. and Manchon, A. and Marti, X. and Wunderlich, J. and Felser, C.},
 title = {The multiple directions of antiferromagnetic spintronics},
 volume = {14},
 copyright = {2018 The Publisher},
 issn = {1745-2473, 1745-2481},
 url = {https://doi.org/10.1038/s41567-018-0063-6},
 doi = {10.1038/s41567-018-0063-6},
 abstract = {New developments in spintronics based on antiferromagnetic materials show promise for improved fundamental understanding and applications in technology.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Nat. Phys.},
 month = mar,
 year = {2018},
 pages = {200-203},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{baltz_antiferromagnetic_2018,
 author = {Baltz, V. and Manchon, A. and Tsoi, M. and Moriyama, T. and Ono, T. and Tserkovnyak, Y.},
 title = {Antiferromagnetic spintronics},
 volume = {90},
 url = {https://doi.org/10.1103/revmodphys.90.015005},
 doi = {10.1103/revmodphys.90.015005},
 abstract = {Antiferromagnetic materials could represent the future of spintronic applications thanks to the numerous interesting features they combine: they are robust against perturbation due to magnetic fields, produce no stray fields, display ultrafast dynamics, and are capable of generating large magnetotransport effects. Intense research efforts over the past decade have been invested in unraveling spin transport properties in antiferromagnetic materials. Whether spin transport can be used to drive the antiferromagnetic order and how subsequent variations can be detected are some of the thrilling challenges currently being addressed. Antiferromagnetic spintronics started out with studies on spin transfer and has undergone a definite revival in the last few years with the publication of pioneering articles on the use of spin-orbit interactions in antiferromagnets. This paradigm shift offers possibilities for radically new concepts for spin manipulation in electronics. Central to these endeavors are the need for predictive models, relevant disruptive materials, and new experimental designs. This paper reviews the most prominent spintronic effects described based on theoretical and experimental analysis of antiferromagnetic materials. It also details some of the remaining bottlenecks and suggests possible avenues for future research. This review covers both spin-transfer-related effects, such as spin-transfer torque, spin penetration length, domain-wall motion, and {\textquotedblleft }magnetization{\textquotedblright } dynamics, and spin-orbit related phenomena, such as (tunnel) anisotropic magnetoresistance, spin Hall, and inverse spin galvanic effects. Effects related to spin caloritronics, such as the spin Seebeck effect, are linked to the transport of magnons in antiferromagnets. The propagation of spin waves and spin superfluids in antiferromagnets is also covered.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Rev. Mod. Phys.},
 month = feb,
 year = {2018},
 pages = {015005},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0034-6861, 1539-0756},
}

@article{jungwirth_antiferromagnetic_2016,
 author = {Jungwirth, T. and Marti, X. and Wadley, P. and Wunderlich, J.},
 title = {Antiferromagnetic spintronics},
 volume = {11},
 copyright = {2016 Nature Publishing Group, a division of Macmillan Publishers Limited. All Rights Reserved.},
 issn = {1748-3387, 1748-3395},
 url = {https://doi.org/10.1038/nnano.2016.18},
 doi = {10.1038/nnano.2016.18},
 abstract = {This article reviews efforts to control and monitor the magnetization in antiferromagnetic materials, as well as the prospects for antiferromagnetic spintronics applications.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Nat. Nanotechnol.},
 month = mar,
 year = {2016},
 pages = {231-241},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{wadley_electrical_2016,
 author = {Wadley, P. and Howells, B. and elezny, J. and Andrews, C. and Hills, V. and Campion, R.P. and Novak, V. and Olejnik, K. and Maccherozzi, F. and Dhesi, S.S. and Martin, S.Y. and Wagner, T. and Wunderlich, J. and Freimuth, F. and Mokrousov, Y. and Kune, J. and Chauhan, J.S. and Grzybowski, M.J. and Rushforth, A.W. and Edmonds, K.W. and Gallagher, B.L. and Jungwirth, T.},
 title = {Electrical switching of an antiferromagnet},
 volume = {351},
 copyright = {Copyright {\copyright } 2016, American Association for the Advancement of Science},
 issn = {0036-8075, 1095-9203},
 url = {https://doi.org/10.1126/science.aab1031},
 doi = {10.1126/science.aab1031},
 abstract = {Manipulating a stubborn magnet Spintronics is an alternative to conventional electronics, based on using the electron's spin rather than its charge. Spintronic devices, such as magnetic memory, have traditionally used ferromagnetic materials to encode the 1's and 0's of the binary code. A weakness of this approach{---}that strong magnetic fields can erase the encoded information{---}could be avoided by using antiferromagnets instead of ferromagnets. But manipulating the magnetic ordering of antiferromagnets is tricky. Now, Wadley others have found a way (see the Perspective by Marrows). Running currents along specific directions in the thin films of the antiferromagnetic compound CuMnAs reoriented the magnetic domains in the material. Science, this issue p. 587; see also p. 558 Antiferromagnets are hard to control by external magnetic fields because of the alternating directions of magnetic moments on individual atoms and the resulting zero net magnetization. However, relativistic quantum mechanics allows for generating current-induced internal fields whose sign alternates with the periodicity of the antiferromagnetic lattice. Using these fields, which couple strongly to the antiferromagnetic order, we demonstrate room-temperature electrical switching between stable configurations in antiferromagnetic CuMnAs thin-film devices by applied current with magnitudes of order 106 ampere per square centimeter. Electrical writing is combined in our solid-state memory with electrical readout and the stored magnetic state is insensitive to and produces no external magnetic field perturbations, which illustrates the unique merits of antiferromagnets for spintronics. Transport and optical measurements are used to demonstrate the switching of domains in the antiferromagnetic compound CuMnAs. [Also see Perspective by Marrows] Transport and optical measurements are used to demonstrate the switching of domains in the antiferromagnetic compound CuMnAs. [Also see Perspective by Marrows]},
 number = {6273},
 urldate = {2019-11-20},
 journal = {Science},
 month = jan,
 year = {2016},
 pmid = {26841431},
 pages = {587-590},
 source = {Crossref},
 publisher = {American Association for the Advancement of Science (AAAS)},
}

@article{gomonay_spintronics_2014,
 author = {Gomonay, E.V. and Loktev, V.M.},
 title = {Spintronics of antiferromagnetic systems {(Review} Article)},
 volume = {40},
 issn = {1063-777X, 1090-6517},
 url = {https://doi.org/10.1063/1.4862467},
 doi = {10.1063/1.4862467},
 number = {1},
 urldate = {2019-11-20},
 journal = {Low Temp. Phys.},
 month = jan,
 year = {2014},
 pages = {17-35},
 source = {Crossref},
 publisher = {AIP Publishing},
}

@article{macdonald_antiferromagnetic_2011,
 author = {MacDonald, A.H. and Tsoi, M.},
 title = {Antiferromagnetic metal spintronics},
 volume = {369},
 url = {https://doi.org/10.1098/rsta.2011.0014},
 doi = {10.1098/rsta.2011.0014},
 abstract = {In this brief review, we explain the theoretical basis for the notion that spin-transfer torques (STTs) and giant-magnetoresistance effects can, in principle, occur in circuits containing only normal and antiferromagnetic (AFM) materials, and for the notion that antiferromagnets can play a role in STT phenomena in circuits containing both ferromagnetic and AFM elements. We review the experimental literature that provides partial evidence for these AFM spintronic effects but demonstrates that, like exchange-bias effects, they are sensitive to details of interface structure that are not always under experimental control. Finally, we speculate briefly on some strategies that might advance progress.},
 number = {1948},
 urldate = {2019-11-20},
 journal = {Proc. R. Soc. A},
 month = aug,
 year = {2011},
 pages = {3098-3114},
 source = {Crossref},
 publisher = {The Royal Society},
 issn = {1364-503X, 1471-2962},
}

@article{noauthor_devices_2018,
 title = {Devices with a spin},
 volume = {1},
 copyright = {2018 Springer Nature Limited},
 issn = {2520-1131},
 url = {https://doi.org/10.1038/s41928-018-0174-1},
 doi = {10.1038/s41928-018-0174-1},
 abstract = {In pursuit of the spin transistor and alternative memory technologies.},
 number = {11},
 urldate = {2019-11-20},
 journal = {Nat. Electron.},
 month = nov,
 year = {2018},
 pages = {571-571},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{kent_new_2015,
 author = {Kent, Andrew D. and Worledge, Daniel C.},
 title = {A new spin on magnetic memories},
 volume = {10},
 copyright = {2015 Nature Publishing Group, a division of Macmillan Publishers Limited. All Rights Reserved.},
 issn = {1748-3387, 1748-3395},
 url = {https://doi.org/10.1038/nnano.2015.24},
 doi = {10.1038/nnano.2015.24},
 abstract = {Solid-state memory devices with all-electrical read and write operations might lead to faster, cheaper information storage.},
 number = {3},
 urldate = {2019-11-20},
 journal = {Nat. Nanotechnol.},
 month = mar,
 year = {2015},
 pages = {187-191},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{bhatti_spintronics_2017,
 author = {Bhatti, Sabpreet and Sbiaa, Rachid and Hirohata, Atsufumi and Ohno, Hideo and Fukami, Shunsuke and Piramanayagam, S.N.},
 title = {Spintronics based random access memory: {A} review},
 volume = {20},
 issn = {1369-7021},
 
 url = {https://doi.org/10.1016/j.mattod.2017.07.007},
 doi = {10.1016/j.mattod.2017.07.007},
 abstract = {This article reviews spintronics based memories, in particular, magnetic random access memory (MRAM) in a systematic manner. Debuted as a humble 4Mb product by FreeScale in 2006, the MRAM has grown to a 256Mb product of Everspin in 2016. During this period, MRAM has overcome several hurdles and have reached a stage, where the potential for MRAM is very promising. One of the main hurdles that the MRAM overcome between 2006 and 2016 is the way the information is written. The 4Mb MRAM used a magnetic field based switching technology that would be almost impossible to scale below 100nm. The 256Mb MRAM, on the other hand uses a different writing mechanism based on Spin Transfer Torque (STT), which is scalable to very low dimensions. In addition to the difference in the writing mechanism, there has also been a major shift in the storage material. Whereas the 4Mb MRAM used materials with in-plane magnetic anisotropy, the 256Mb MRAM uses materials with a perpendicular magnetic anisotropy (PMA). MRAM based on PMA is also scalable to much higher densities. The paper starts with a brief history of memory technologies, followed by a brief description of the working principles of MRAM for novice. Reading information from MRAM, the technologies, materials and the physics behind reading of bits in MRAM are described in detail. As a next step, the physics and technologies involved in writing information are described. The magnetic field based writing and its limitations are described first, followed by an explanation of STT mechanism. The materials and physics behind storage of information is described next. MRAMs with in-plane magnetization, their layered material structure and the disadvantages are described first, followed by the advantages of MRAMs with perpendicular magnetization, their advantages etc. The technologies to improve writability and potential challenges and reliability issues are discussed next. Some of the future technologies that might help the industry to move beyond the conventional MRAM technology are discussed at the end of the paper, followed by a summary and an outlook.},
 number = {9},
 urldate = {2019-11-20},
 journal = {Mater. Today},
 month = nov,
 year = {2017},
 pages = {530-548},
 source = {Crossref},
 publisher = {Elsevier BV},
}

@article{sinova_new_2012,
 author = {Sinova, Jairo and Žutić, Igor},
 title = {New moves of the spintronics tango},
 volume = {11},
 copyright = {2012 Nature Publishing Group, a division of Macmillan Publishers Limited. All Rights Reserved.},
 issn = {1476-1122, 1476-4660},
 url = {https://doi.org/10.1038/nmat3304},
 doi = {10.1038/nmat3304},
 abstract = {The ability of spintronics to re-energize itself in directions that germinate new subfields has made it one of the most fertile grounds for basic research aimed at future applications. A brief overview of the connections between five emerging subfields suggests exciting things to come.},
 number = {5},
 urldate = {2019-11-20},
 journal = {Nat. Mater.},
 month = apr,
 year = {2012},
 pages = {368-371},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{bader_spintronics_2010,
 author = {Bader, S.D. and Parkin, S.S.P.},
 title = {Spintronics},
 volume = {1},
 url = {https://doi.org/10.1146/annurev-conmatphys-070909-104123},
 doi = {10.1146/annurev-conmatphys-070909-104123},
 abstract = {Spintronics encompasses the ever-evolving field of magnetic electronics. It is an applied discipline that is so forward-looking that much of the research that supports it is at the center of basic condensed matter physics. This review provides a perspective on recent developments in switching magnetic moments by spin-polarized currents, electric fields, and photonic fields. Developments in the field continue to be strongly dependent on the exploration and discovery of novel material systems. An array of novel transport and thermoelectric effects dependent on the interplay between spin and charge currents have been explored theoretically and experimentally in recent years. The review highlights select areas that hold promise for future investigation and attempts to unify and further inform the field.},
 number = {1},
 urldate = {2019-11-20},
 journal = {Annu. Rev. Condens. Matter Phys.},
 year = {2010},
 pages = {71-88},
 source = {Crossref},
 publisher = {Annual Reviews},
 issn = {1947-5454, 1947-5462},
 month = aug,
}

@article{sato_two-terminal_2018,
 author = {Sato, Noriyuki and Xue, Fen and White, Robert M. and Bi, Chong and Wang, Shan X.},
 title = {Two-terminal spin--orbit torque magnetoresistive random access memory},
 volume = {1},
 copyright = {2018 The Author(s), under exclusive licence to Springer Nature Limited},
 issn = {2520-1131},
 url = {https://doi.org/10.1038/s41928-018-0131-z},
 doi = {10.1038/s41928-018-0131-z},
 abstract = {Spin{--}orbit torque switching in a two-terminal magnetoresistive random access memory cell can reduce critical write current by more than 70\% compared with an equivalent spin-transfer torque device.},
 number = {9},
 urldate = {2019-11-20},
 journal = {Nat. Electron.},
 month = sep,
 year = {2018},
 pages = {508-511},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
}

@article{jourdan_epitaxial_2015,
 author = {Jourdan, M and Bräuning, H and Sapozhnik, A and Elmers, H-J and Zabel, H and Kläui, M},
 title = {Epitaxial {Mn2Au} thin films for antiferromagnetic spintronics},
 volume = {48},
 issn = {0022-3727, 1361-6463},
 url = {https://doi.org/10.1088/0022-3727/48/38/385001},
 doi = {10.1088/0022-3727/48/38/385001},
 number = {38},
 urldate = {2019-11-20},
 journal = {J. Phys. D: Appl. Phys.},
 month = aug,
 year = {2015},
 pages = {385001},
 source = {Crossref},
 publisher = {IOP Publishing},
}

@article{ivanPRL,
 author = {Ado, I.A. and Dmitriev, I.A. and Ostrovsky, P.M. and Titov, M.},
 title = {Anomalous Hall Effect in a {2D} Rashba Ferromagnet},
 journal = {Phys. Rev. Lett.},
 volume = {117},
 issue = {4},
 pages = {046601},
 numpages = {5},
 year = {2016},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.117.046601},
 url = {https://doi.org/10.1103/physrevlett.117.046601},
 number = {4},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
 month = jul,
}

@article{Ghosh18,
 author = {Ghosh, S. and Manchon, A.},
 title = {Spin-orbit torque in a three-dimensional topological insulator--ferromagnet heterostructure: {Crossover} between bulk and surface transport},
 journal = {Phys. Rev. B},
 volume = {97},
 issue = {13},
 pages = {134402},
 numpages = {10},
 year = {2018},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.97.134402},
 url = {https://doi.org/10.1103/physrevb.97.134402},
 number = {13},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
 month = apr,
}

@article{ivanPRB,
 author = {Ado, I.A. and Dmitriev, I.A. and Ostrovsky, P.M. and Titov, M.},
 title = {Sensitivity of the anomalous Hall effect to disorder correlations},
 journal = {Phys. Rev. B},
 volume = {96},
 issue = {23},
 pages = {235148},
 numpages = {13},
 year = {2017},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.96.235148},
 url = {https://doi.org/10.1103/physrevb.96.235148},
 number = {23},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
 month = dec,
}

@article{katsnelson15,
 author = {Ferreiros, Yago and Buijnsters, F.J. and Katsnelson, M.I.},
 title = {{Dirac} electrons and domain walls: {A} realization in junctions of ferromagnets and topological insulators},
 journal = {Phys. Rev. B},
 volume = {92},
 issue = {8},
 pages = {085416},
 numpages = {15},
 year = {2015},
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.92.085416},
 url = {https://doi.org/10.1103/physrevb.92.085416},
 number = {8},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
 month = aug,
}

@article{kong_rapid_2011,
 author = {Kong, Desheng and Cha, Judy J. and Lai, Keji and Peng, Hailin and Analytis, James G. and Meister, Stefan and Chen, Yulin and Zhang, Hai-Jun and Fisher, Ian R. and Shen, Zhi-Xun and Cui, Yi},
 title = {Rapid Surface Oxidation as a Source of Surface Degradation Factor for {Bi2Se3}},
 volume = {5},
 issn = {1936-0851, 1936-086X},
 url = {https://doi.org/10.1021/nn200556h},
 doi = {10.1021/nn200556h},
 abstract = {Bismuth selenide (Bi2Se3) is a topological insulator with metallic surface states (SS) residing in a large bulk bandgap. In experiments, synthesized Bi2Se3 is often heavily n-type doped due to selenium vacancies. Furthermore, it is discovered from experiments on bulk single crystals that Bi2Se3 gets additional n-type doping after exposure to the atmosphere, thereby reducing the relative contribution of SS in total conductivity. In this article, transport measurements on Bi2Se3 nanoribbons provide additional evidence of such environmental doping process. Systematic surface composition analyses by X-ray photoelectron spectroscopy reveal fast formation and continuous growth of native oxide on Bi2Se3 under ambient conditions. In addition to n-type doping at the surface, such surface oxidation is likely the material origin of the degradation of topological SS. Appropriate surface passivation or encapsulation may be required to probe topological SS of Bi2Se3 by transport measurements.},
 number = {6},
 urldate = {2019-02-21},
 journal = {ACS Nano},
 year = {2011},
 pages = {4698-4703},
 file = {ACS Full Text PDF w/ Links:/scratch/zotero/storage/QXC6H5Z7/Kong et al. - 2011 - Rapid Surface Oxidation as a Source of Surface Deg.pdf:application/pdf;ACS Full Text Snapshot:/scratch/zotero/storage/RBWI2E3I/nn 56h.html:text/html},
 source = {Crossref},
 publisher = {American Chemical Society (ACS)},
 month = may,
}

@article{kamboj_probing_2017,
 author = {Kamboj, Varun S. and Singh, Angadjit and Ferrus, Thierry and Beere, Harvey E. and Duffy, Liam B. and Hesjedal, Thorsten and Barnes, Crispin H.W. and Ritchie, David A.},
 title = {Probing the Topological Surface State in {Bi2Se3} Thin Films Using Temperature-Dependent Terahertz Spectroscopy},
 volume = {4},
 issn = {2330-4022, 2330-4022},
 url = {https://doi.org/10.1021/acsphotonics.7b00492},
 doi = {10.1021/acsphotonics.7b00492},
 abstract = {Strong spin-momentum coupling in topological insulators give rise to topological surface states, protected against disorder scattering by time reversal symmetry. The study of these exotic quantum states not only provides an opportunity to explore fundamental phenomenon in condensed matter physics such as the spin hall effect, but also lays the foundation for applications in quantum computing to spintronics. Conventional electrical measurements suffer from substantial bulk interference, making it difficult to clearly identify topological surface state from the bulk. We use terahertz time-domain spectroscopy to study the temperature-dependent optical behavior of a 23quintuple-thick film of bismuth selenide (Bi2Se3) allowing the deconvolution of the surface state response from the bulk. The signatures of the topological surface state at low temperatures ({\textless } 30 K) with the optical conductance of Bi2Se3 exhibiting a metallic behavior are observed. Measurement of carrier dynamics, obtain an optical mobility, exceeding 2000 cm2/Vs at 4 K, indicative of a surfacedominated response. A scattering lifetime of {\textasciitilde }0.18 ps and a carrier density of 6$\times$1012 cm-2 at 4 K were obtained from the terahertz time-domain spectroscopy measurement. The terahertz conductance spectra reveal characteristic features at {\textasciitilde }1.9 THz, attributed to the optical phonon mode, which becomes less prominent with falling temperature. The electrical transport measurements reveal weak antilocalization behavior in our Bi2Se3 sample, consistent with the presence of a topological surface state.},
 
 number = {11},
 urldate = {2019-02-21},
 journal = {ACS Photonics},
 year = {2017},
 pages = {2711-2718},
 file = {Kamboj et al. - 2017 - Probing the Topological Surface State in Bi sub2.pdf:/scratch/zotero/storage/RXVQSKSN/Kamboj et al. - 2017 - Probing the Topological Surface State in Bi sub2.pdf:application/pdf},
 source = {Crossref},
 publisher = {American Chemical Society (ACS)},
 month = oct,
}

@article{huang_enhancement_2017,
 author = {Huang, Shiu-Ming and Huang, Shih-Jhe and Hsu, Ching and Wadekar, Paritosh V. and Yan, You-Jhih and Yu, Shih-Hsun and Chou, Mitch},
 title = {Enhancement of carrier transport characteristic in the {Sb2Se2Te} topological insulators by N2 adsorption},
 volume = {7},
 issn = {2045-2322},
 url = {https://doi.org/10.1038/s41598-017-05369-y},
 doi = {10.1038/s41598-017-05369-y},
 pages = {5133},
 number = {1},
 urldate = {2019-02-21},
 journal = {Sci. Rep.},
 year = {2017},
 file = {Huang et al. - 2017 - Enhancement of carrier transport characteristic in.pdf:/scratch/zotero/storage/3B6H6JSA/Huang et al. - 2017 - Enhancement of carrier transport characteristic in.pdf:application/pdf},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 month = jul,
}

@article{xiang_transport_2014,
 author = {Xiang, F.X. and Wang, X.L. and Dou, S.X.},
 title = {Transport evidence of robust topological surface state in {BiTeCl} single crystals, the first strong inversion asymmetric topological insulator},
 url = {http://arxiv.org/abs/1401.6732},
 abstract = {Three-dimensional (3D) topological insulators (TIs) are new forms of quantum matter that are characterized by their insulating bulk state and exotic metallic surface state, which hosts helical Dirac fermions1-2. Very recently, BiTeCl, one of the polar semiconductors, has been discovered by angle-resolved photoemission spectroscopy to be the first strong inversion asymmetric topological insulator (SIATI). In contrast to the previously discovered 3D TIs with inversion symmetry, the SIATI are expected to exhibit novel topological phenomena, including crystalline-surface-dependent topological surface states, intrinsic topological p-n junctions, and pyroelectric and topological magneto-electric effects3. Here, we report the first transport evidence for the robust topological surface state in the SIATI BiTeCl via observation of Shubnikov-de Haas (SdH) oscillations, which exhibit the 2D nature of the Fermi surface and pi Berry phase. The n = 1 Landau quantization of the topological surface state is observed at B . 12 T without gating, and the Fermi level is only 58.8 meV above the Dirac point, which gives rise to small effective mass, 0.055me, and quite large mobility, 4490 cm2s-1. Our findings will pave the way for future transport exploration of other new topological phenomena and potential applications for strong inversion asymmetric topological insulators.},
 urldate = {2019-02-21},
 journal = {arXiv:1401.6732 [cond-mat]},
 year = {2014},
 keywords = {Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter, Condensed Matter - Strongly Correlated Electrons},
 annote = {Comment: 10 pages, 3 figures, 1 table, references updated},
 file = {arXiv\:1401.6732 PDF:/scratch/zotero/storage/KJAKM6AS/Xiang et al. - 2014 - Transport evidence of robust topological surface s.pdf:application/pdf;arXiv.org Snapshot:/scratch/zotero/storage/Y6CXDN7C/1401.html:text/html},
}

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 author = {Rammer, J. and Smith, H.},
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 url = {https://doi.org/10.1103/revmodphys.58.323},
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 urldate = {2016-06-01},
 journal = {Rev. Mod. Phys.},
 year = {1986},
 pages = {323-359},
 file = {Quantum field-theoretical methods in transport theory of metals - RevModPhys.58.323:/scratch/zotero/storage/UJ7BIAUG/RevModPhys.58.pdf:application/pdf},
 doi = {10.1103/revmodphys.58.323},
 source = {Crossref},
 publisher = {American Physical Society (APS)},
 issn = {0034-6861},
 month = apr,
}

@article{maleev1976corrections,
 author = {Maleev, SV and Toperverg, BP},
 title = {Corrections to diffusion and conductivity in the field of randomly distributed force centers},
 journal = {JETP},
 volume = {42},
 pages = {734},
 year = {1976},
}

@article{maleev1975corrections,
 author = {Maleev, SV and Toperverg, BP},
 title = {Corrections to diffusion and conductivity in the field of randomly distributed force centers},
 journal = {Zh. Eksp. Teor. Fiz},
 volume = {69},
 pages = {1440--1452},
 year = {1975},
}

@book{altshuler1985electron,
 author = {Altshuler, Boris L and Aronov, A Gh},
 title = {Electron--electron interaction in disordered conductors},
 booktitle = {Modern Problems in condensed matter sciences},
 volume = {10},
 pages = {155},
 year = {1985},
 publisher = {Elsevier},
}

@article{Gong2017,
 author = {Gong, Cheng and Li, Lin and Li, Zhenglu and Ji, Huiwen and Stern, Alex and Xia, Yang and Cao, Ting and Bao, Wei and Wang, Chenzhe and Wang, Yuan and Qiu, Z.Q. and Cava, R.J. and Louie, Steven G. and Xia, Jing and Zhang, Xiang},
 journal = {Nature},
 month = apr,
 pages = {265-269},
 publisher = {Springer Science and Business Media LLC},
 title = {Discovery of intrinsic ferromagnetism in two-dimensional van der Waals crystals},
 url = {https://doi.org/10.1038/nature22060},
 volume = {546},
 year = {2017},
 doi = {10.1038/nature22060},
 number = {7657},
 source = {Crossref},
 issn = {0028-0836, 1476-4687},
}

@article{Herrero2017,
 author = {Huang, Bevin and Clark, Genevieve and Navarro-Moratalla, Efrén and Klein, Dahlia R. and Cheng, Ran and Seyler, Kyle L. and Zhong, Ding and Schmidgall, Emma and McGuire, Michael A. and Cobden, David H. and Yao, Wang and Xiao, Di and Jarillo-Herrero, Pablo and Xu, Xiaodong},
 journal = {Nature},
 month = jun,
 pages = {270-273},
 publisher = {Springer Science and Business Media LLC},
 title = {Layer-dependent ferromagnetism in a van der Waals crystal down to the monolayer limit},
 url = {https://doi.org/10.1038/nature22391},
 volume = {546},
 year = {2017},
 doi = {10.1038/nature22391},
 number = {7657},
 source = {Crossref},
 issn = {0028-0836, 1476-4687},
}

@article{Burch2018,
 author = {Burch, Kenneth S. and Mandrus, David and Park, Je-Geun},
 doi = {10.1038/s41586-018-0631-z},
 isbn = {1476-4687},
 journal = {Nature},
 number = {7729},
 pages = {47-52},
 title = {Magnetism in two-dimensional van der Waals materials},
 url = {https://doi.org/10.1038/s41586-018-0631-z},
 volume = {563},
 year = {2018},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {0028-0836, 1476-4687},
 month = oct,
}

@article{Tokmachev2018,
 author = {Tokmachev, Andrey M. and Averyanov, Dmitry V. and Parfenov, Oleg E. and Taldenkov, Alexander N. and Karateev, Igor A. and Sokolov, Ivan S. and Kondratev, Oleg A. and Storchak, Vyacheslav G.},
 title = {Emerging two-dimensional ferromagnetism in silicene materials},
 volume = {9},
 pages = {1672},
 year = {2018},
 doi = {10.1038/s41467-018-04012-2},
 publisher = {Springer Science and Business Media LLC},
 url = {https://doi.org/10.1038/s41467-018-04012-2},
 journal = {Nat. Commun.},
 number = {1},
 source = {Crossref},
 issn = {2041-1723},
 month = apr,
}

@article{Gong2019,
 author = {Gong, Cheng and Zhang, Xiang},
 title = {Two-dimensional magnetic crystals and emergent heterostructure devices},
 volume = {363},
 number = {6428},
 year = {2019},
 doi = {10.1126/science.aav4450},
 publisher = {American Association for the Advancement of Science (AAAS)},
 issn = {0036-8075, 1095-9203},
 url = {https://doi.org/10.1126/science.aav4450},
 journal = {Science},
 pages = {eaav4450},
 source = {Crossref},
 month = feb,
}

@article{Novoselov2019,
 author = {Gibertini, M. and Koperski, M. and Morpurgo, A.F. and Novoselov, K.S.},
 doi = {10.1038/s41565-019-0438-6},
 isbn = {1748-3395},
 journal = {Nat. Nanotechnol.},
 number = {5},
 pages = {408-419},
 title = {Magnetic {2D} materials and heterostructures},
 url = {https://doi.org/10.1038/s41565-019-0438-6},
 volume = {14},
 year = {2019},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {1748-3387, 1748-3395},
 month = may,
}

@article{Cortie2019,
 author = {Cortie, David L. and Causer, Grace L. and Rule, Kirrily C. and Fritzsche, Helmut and Kreuzpaintner, Wolfgang and Klose, Frank},
 title = {Two-Dimensional Magnets: {Forgotten} History and Recent Progress towards Spintronic Applications},
 journal = {Adv. Funct. Mater.},
 volume = {0},
 number = {0},
 pages = {1901414},
 doi = {10.1002/adfm.201901414},
 url = {https://doi.org/10.1002/adfm.201901414},
 year = {2019},
 source = {Crossref},
 publisher = {Wiley},
 issn = {1616-301X, 1616-3028},
 month = may,
}

@article{Huang2018,
 author = {Huang, Bevin and Clark, Genevieve and Klein, Dahlia R. and MacNeill, David and Navarro-Moratalla, Efrén and Seyler, Kyle L. and Wilson, Nathan and McGuire, Michael A. and Cobden, David H. and Xiao, Di and Yao, Wang and Jarillo-Herrero, Pablo and Xu, Xiaodong},
 doi = {10.1038/s41565-018-0121-3},
 journal = {Nat. Nanotechnol.},
 number = {7},
 pages = {544-548},
 title = {Electrical control of {2D} magnetism in bilayer {CrI3}},
 url = {https://doi.org/10.1038/s41565-018-0121-3},
 volume = {13},
 year = {2018},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {1748-3387, 1748-3395},
 month = apr,
}

@article{Shengwei2018,
 author = {Jiang, Shengwei and Shan, Jie and Mak, Kin Fai},
 doi = {10.1038/s41563-018-0040-6},
 isbn = {1476-4660},
 journal = {Nat. Mater.},
 number = {5},
 pages = {406-410},
 title = {Electric-field switching of two-dimensional van der Waals magnets},
 url = {https://doi.org/10.1038/s41563-018-0040-6},
 volume = {17},
 year = {2018},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {1476-1122, 1476-4660},
 month = mar,
}

@article{Wang2018,
 author = {Wang, Zhi and Zhang, Tongyao and Ding, Mei and Dong, Baojuan and Li, Yanxu and Chen, Maolin and Li, Xiaoxi and Huang, Jianqi and Wang, Hanwen and Zhao, Xiaotian and Li, Yong and Li, Da and Jia, Chuankun and Sun, Lidong and Guo, Huaihong and Ye, Yu and Sun, Dongming and Chen, Yuansen and Yang, Teng and Zhang, Jing and Ono, Shimpei and Han, Zheng and Zhang, Zhidong},
 doi = {10.1038/s41565-018-0186-z},
 journal = {Nat. Nanotechnol.},
 number = {7},
 pages = {554-559},
 title = {Electric-field control of magnetism in a few-layered van der Waals ferromagnetic semiconductor},
 url = {https://doi.org/10.1038/s41565-018-0186-z},
 volume = {13},
 year = {2018},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {1748-3387, 1748-3395},
 month = jul,
}

@article{Deng2018,
 author = {Deng, Yujun and Yu, Yijun and Song, Yichen and Zhang, Jingzhao and Wang, Nai Zhou and Sun, Zeyuan and Yi, Yangfan and Wu, Yi Zheng and Wu, Shiwei and Zhu, Junyi and Wang, Jing and Chen, Xian Hui and Zhang, Yuanbo},
 doi = {10.1038/s41586-018-0626-9},
 journal = {Nature},
 number = {7729},
 pages = {94-99},
 title = {Gate-tunable room-temperature ferromagnetism in two-dimensional {Fe3GeTe2}},
 url = {https://doi.org/10.1038/s41586-018-0626-9},
 volume = {563},
 year = {2018},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {0028-0836, 1476-4687},
 month = oct,
}

@article{Nagler2019,
 author = {Takagi, Hidenori and Takayama, Tomohiro and Jackeli, George and Khaliullin, Giniyat and Nagler, Stephen E.},
 doi = {10.1038/s42254-019-0038-2},
 isbn = {2522-5820},
 journal = {Nat. Rev. Phys.},
 number = {4},
 pages = {264-280},
 title = {Concept and realization of Kitaev quantum spin liquids},
 url = {https://doi.org/10.1038/s42254-019-0038-2},
 volume = {1},
 year = {2019},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {2522-5820},
 month = mar,
}

@article{Gordon2019,
 author = {Gordon, Jacob S. and Catuneanu, Andrei and Sørensen, Erik S. and Kee, Hae-Young},
 doi = {10.1038/s41467-019-10405-8},
 isbn = {2041-1723},
 journal = {Nat. Commun.},
 number = {1},
 pages = {2470},
 title = {Theory of the field-revealed Kitaev spin liquid},
 url = {https://doi.org/10.1038/s41467-019-10405-8},
 volume = {10},
 year = {2019},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {2041-1723},
 month = jun,
}

@article{Livanas2019,
 author = {Livanas, G. and Sigrist, M. and Varelogiannis, G.},
 doi = {10.1038/s41598-019-42558-3},
 isbn = {2045-2322},
 journal = {Sci. Rep.},
 number = {1},
 pages = {6259},
 title = {Alternative paths to realize Majorana Fermions in Superconductor-Ferromagnet Heterostructures},
 url = {https://doi.org/10.1038/s41598-019-42558-3},
 volume = {9},
 year = {2019},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {2045-2322},
 month = apr,
}

@article{Mokrousov2019,
 author = {Niu, Chengwang and Hanke, Jan-Philipp and Buhl, Patrick M. and Zhang, Hongbin and Plucinski, Lukasz and Wortmann, Daniel and Blügel, Stefan and Bihlmayer, Gustav and Mokrousov, Yuriy},
 doi = {10.1038/s41467-019-10930-6},
 isbn = {2041-1723},
 journal = {Nat. Commun.},
 number = {1},
 pages = {3179},
 title = {Mixed topological semimetals driven by orbital complexity in two-dimensional ferromagnets},
 url = {https://doi.org/10.1038/s41467-019-10930-6},
 volume = {10},
 year = {2019},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {2041-1723},
 month = jul,
}

@article{Wang2018a,
 author = {Wang, Zhe and Gutiérrez-Lezama, Ignacio and Ubrig, Nicolas and Kroner, Martin and Gibertini, Marco and Taniguchi, Takashi and Watanabe, Kenji and Imamoğlu, Ataç and Giannini, Enrico and Morpurgo, Alberto F.},
 doi = {10.1038/s41467-018-04953-8},
 journal = {Nat. Commun.},
 number = {1},
 pages = {2516},
 title = {Very large tunneling magnetoresistance in layered magnetic semiconductor {CrI3}},
 url = {https://doi.org/10.1038/s41467-018-04953-8},
 volume = {9},
 year = {2018},
 source = {Crossref},
 publisher = {Springer Science and Business Media LLC},
 issn = {2041-1723},
 month = jun,
}

@article{Song2018,
 author = {Song, Tiancheng and Cai, Xinghan and Tu, Matisse Wei-Yuan and Zhang, Xiaoou and Huang, Bevin and Wilson, Nathan P. and Seyler, Kyle L. and Zhu, Lin and Taniguchi, Takashi and Watanabe, Kenji and McGuire, Michael A. and Cobden, David H. and Xiao, Di and Yao, Wang and Xu, Xiaodong},
 title = {Giant tunneling magnetoresistance in spin-filter van der Waals heterostructures},
 volume = {360},
 number = {6394},
 pages = {1214-1218},
 year = {2018},
 doi = {10.1126/science.aar4851},
 publisher = {American Association for the Advancement of Science (AAAS)},
 issn = {0036-8075, 1095-9203},
 url = {https://doi.org/10.1126/science.aar4851},
 journal = {Science},
 source = {Crossref},
 month = may,
}

@article{Klein2018,
 author = {Klein, D.R. and MacNeill, D. and Lado, J.L. and Soriano, D. and Navarro-Moratalla, E. and Watanabe, K. and Taniguchi, T. and Manni, S. and Canfield, P. and Fernández-Rossier, J. and Jarillo-Herrero, P.},
 title = {Probing magnetism in {2D} van der Waals crystalline insulators via electron tunneling},
 volume = {360},
 number = {6394},
 pages = {1218-1222},
 year = {2018},
 doi = {10.1126/science.aar3617},
 publisher = {American Association for the Advancement of Science (AAAS)},
 issn = {0036-8075, 1095-9203},
 url = {https://doi.org/10.1126/science.aar3617},
 journal = {Science},
 source = {Crossref},
 month = may,
}

@article{Kim2018,
 author = {Kim, Hyun Ho and Yang, Bowen and Patel, Tarun and Sfigakis, Francois and Li, Chenghe and Tian, Shangjie and Lei, Hechang and Tsen, Adam W.},
 doi = {10.1021/acs.nanolett.8b01552},
 journal = {Nano Lett.},
 number = {8},
 pages = {4885-4890},
 title = {One Million Percent Tunnel Magnetoresistance in a Magnetic van der Waals Heterostructure},
 url = {https://doi.org/10.1021/acs.nanolett.8b01552},
 volume = {18},
 year = {2018},
 source = {Crossref},
 publisher = {American Chemical Society (ACS)},
 issn = {1530-6984, 1530-6992},
 month = jul,
}

@article{Xing2019,
 author = {Xing, Wenyu and Qiu, Luyi and Wang, Xirui and Yao, Yunyan and Ma, Yang and Cai, Ranran and Jia, Shuang and Xie, X.C. and Han, Wei},
 title = {Magnon Transport in Quasi-Two-Dimensional van der Waals Antiferromagnets},
 journal = {Phys. Rev. X},
 volume = {9},
 issue = {1},
 pages = {011026},
 numpages = {7},
 year = {2019},
 month = feb,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevx.9.011026},
 url = {https://doi.org/10.1103/physrevx.9.011026},
 number = {1},
 source = {Crossref},
 issn = {2160-3308},
}

@article{Lado2017,
 author = {Lado, J L and Fernández-Rossier, J},
 doi = {10.1088/2053-1583/aa75ed},
 url = {https://doi.org/10.1088/2053-1583/aa75ed},
 year = {2017},
 month = jun,
 publisher = {IOP Publishing},
 volume = {4},
 number = {3},
 pages = {035002},
 title = {On the origin of magnetic anisotropy in two dimensional {CrI} 3},
 journal = {2D Mater.},
 source = {Crossref},
 issn = {2053-1583},
}

@article{Parkin2003,
 author = {Parkin, S. and Jiang, X. and Kaiser, C. and Panchula, A. and Roche, K. and Samant, M.},
 journal = {Proc. IEEE},
 title = {Magnetically engineered spintronic sensors and memory},
 year = {2003},
 volume = {91},
 number = {5},
 pages = {661-680},
 doi = {10.1109/jproc.2003.811807},
 month = may,
 source = {Crossref},
 url = {https://doi.org/10.1109/jproc.2003.811807},
 publisher = {Institute of Electrical and Electronics Engineers (IEEE)},
 issn = {0018-9219},
}

@article{Jogschies2015,
 author = {Jogschies, Lisa and Klaas, Daniel and Kruppe, Rahel and Rittinger, Johannes and Taptimthong, Piriya and Wienecke, Anja and Rissing, Lutz and Wurz, Marc},
 doi = {10.3390/s151128665},
 url = {https://doi.org/10.3390/s151128665},
 year = {2015},
 month = nov,
 publisher = {MDPI AG},
 volume = {15},
 number = {11},
 pages = {28665-28689},
 title = {Recent Developments of Magnetoresistive Sensors for Industrial Applications},
 journal = {Sensors},
 source = {Crossref},
 issn = {1424-8220},
}

@article{Lau2016,
 author = {Lau, Yong-Chang and Betto, Davide and Rode, Karsten and Coey, J.M.D. and Stamenov, Plamen},
 doi = {10.1038/nnano.2016.84},
 url = {https://doi.org/10.1038/nnano.2016.84},
 year = {2016},
 month = may,
 publisher = {Springer Science and Business Media LLC},
 volume = {11},
 pages = {758-762},
 title = {Spin--orbit torque switching without an external field using interlayer exchange coupling},
 journal = {Nat. Nanotechnol.},
 number = {9},
 source = {Crossref},
 issn = {1748-3387, 1748-3395},
}

@article{Fukami2016,
 author = {Fukami, Shunsuke and Zhang, Chaoliang and DuttaGupta, Samik and Kurenkov, Aleksandr and Ohno, Hideo},
 doi = {10.1038/nmat4566},
 url = {https://doi.org/10.1038/nmat4566},
 year = {2016},
 month = feb,
 publisher = {Springer Science and Business Media LLC},
 volume = {15},
 pages = {535-541},
 title = {Magnetization switching by spin--orbit torque in an antiferromagnet--ferromagnet bilayer system},
 journal = {Nat. Mater.},
 number = {5},
 source = {Crossref},
 issn = {1476-1122, 1476-4660},
}

@article{Wadley2016,
 author = {Wadley, P. and others},
 title = {Electrical switching of an antiferromagnet},
 volume = {351},
 number = {6273},
 pages = {587--590},
 year = {2016},
 doi = {10.1126/science.aab1031},
 publisher = {American Association for the Advancement of Science},
 issn = {0036-8075},
 url = {http://science.sciencemag.org/content/351/6273/587},
 journal = {Science},
}

@article{PhysRevMaterials.1.061401,
 author = {Liu, Qian and Yuan, H.Y. and Xia, Ke and Yuan, Zhe},
 title = {Mode-dependent damping in metallic antiferromagnets due to intersublattice spin pumping},
 journal = {Phys. Rev. Mater.},
 volume = {1},
 issue = {6},
 pages = {061401},
 numpages = {6},
 year = {2017},
 month = nov,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevmaterials.1.061401},
 url = {https://doi.org/10.1103/physrevmaterials.1.061401},
 number = {6},
 source = {Crossref},
 issn = {2475-9953},
}

@article{Kamra2018,
 author = {Kamra, Akashdeep and Troncoso, Roberto E. and Belzig, Wolfgang and Brataas, Arne},
 title = {{Gilbert} damping phenomenology for two-sublattice magnets},
 journal = {Phys. Rev. B},
 volume = {98},
 issue = {18},
 pages = {184402},
 numpages = {8},
 year = {2018},
 month = nov,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.98.184402},
 url = {https://doi.org/10.1103/physrevb.98.184402},
 number = {18},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
}

@article{Mahfouzi2018a,
 author = {Mahfouzi, Farzad and Kioussis, Nicholas},
 title = {Damping and antidamping phenomena in metallic antiferromagnets: {An} ab initio study},
 journal = {Phys. Rev. B},
 volume = {98},
 issue = {22},
 pages = {220410},
 numpages = {6},
 year = {2018},
 month = dec,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.98.220410},
 url = {https://doi.org/10.1103/physrevb.98.220410},
 number = {22},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
}

@article{Yuan_2019,
 author = {Yuan, H.Y. and Liu, Qian and Xia, Ke and Yuan, Zhe and Wang, X.R.},
 doi = {10.1209/0295-5075/126/67006},
 url = {https://doi.org/10.1209/0295-5075/126/67006},
 year = {2019},
 month = jul,
 publisher = {IOP Publishing},
 volume = {126},
 number = {6},
 pages = {67006},
 title = {Proper dissipative torques in antiferromagnetic dynamics},
 journal = {EPL},
 source = {Crossref},
 issn = {1286-4854},
}

@article{Tserkovnyak,
 author = {Tserkovnyak, Yaroslav and Brataas, Arne and Bauer, Gerrit E.W. and Halperin, Bertrand I.},
 title = {Nonlocal magnetization dynamics in ferromagnetic heterostructures},
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 pages = {1375-1421},
 numpages = {0},
 year = {2005},
 month = dec,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/revmodphys.77.1375},
 url = {https://doi.org/10.1103/revmodphys.77.1375},
 number = {4},
 source = {Crossref},
 issn = {0034-6861, 1539-0756},
}

@article{Sumit2019,
 author = {Sokolewicz, Robert and Ghosh, Sumit and Yudin, Dmitry and Manchon, Aurélien and Titov, Mikhail},
 title = {Spin-orbit torques in a Rashba honeycomb antiferromagnet},
 journal = {Phys. Rev. B},
 volume = {100},
 issue = {},
 pages = {214403},
 numpages = {},
 year = {2019},
 month = dec,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.100.214403},
 url = {https://doi.org/10.1103/physrevb.100.214403},
 number = {21},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
}

@article{Meinert2018,
 author = {Meinert, Markus and Graulich, Dominik and Matalla-Wagner, Tristan},
 title = {Electrical Switching of Antiferromagnetic {Mn2Au} and the Role of Thermal Activation},
 journal = {Phys. Rev. Applied},
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 pages = {064040},
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 year = {2018},
 month = jun,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevapplied.9.064040},
 url = {https://doi.org/10.1103/physrevapplied.9.064040},
 number = {6},
 source = {Crossref},
 issn = {2331-7019},
}

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 author = {Son, Young-Woo and Cohen, Marvin L. and Louie, Steven G.},
 title = {Energy Gaps in Graphene Nanoribbons},
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 url = {https://doi.org/10.1103/physrevlett.97.216803},
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 source = {Crossref},
 issn = {0031-9007, 1079-7114},
}

@article{Nikolic,
 author = {Nikolić, Branislav K. and Souma, Satofumi and Zârbo, Liviu P. and Sinova, Jairo},
 title = {Nonequilibrium Spin Hall Accumulation in Ballistic Semiconductor Nanostructures},
 journal = {Phys. Rev. Lett.},
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 pages = {046601},
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 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.95.046601},
 url = {https://doi.org/10.1103/physrevlett.95.046601},
 number = {4},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
}

@article{Heinrich2003,
 author = {Heinrich, B. and Woltersdorf, G. and Urban, R. and Simanek, E.},
 title = {Role of dynamic exchange coupling in magnetic relaxations of metallic multilayer films (invited)},
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 pages = {7545-7550},
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 doi = {10.1063/1.1543852},
 url = {https://doi.org/10.1063/1.1543852},
 eprint = {https://doi.org/10.1063/1.1543852},
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 publisher = {AIP Publishing},
 issn = {0021-8979, 1089-7550},
 month = may,
}

@article{Miron2011-400m/s,
 author = {Miron, Ioan Mihai and Moore, Thomas and Szambolics, Helga and Buda-Prejbeanu, Liliana Daniela and Auffret, Stéphane and Rodmacq, Bernard and Pizzini, Stefania and Vogel, Jan and Bonfim, Marlio and Schuhl, Alain and Gaudin, Gilles},
 title = {Fast current-induced domain-wall motion controlled by the Rashba effect},
 journal = {Nat. Mater.},
 volume = {10},
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 pages = {419-423},
 year = {2011},
 publisher = {Springer Science and Business Media LLC},
 url = {https://doi.org/10.1038/nmat3020},
 doi = {10.1038/nmat3020},
 source = {Crossref},
 issn = {1476-1122, 1476-4660},
 month = may,
}

@article{Chappert2007review,
 author = {Chappert, Claude and Fert, Albert and Van Dau, Frédéric Nguyen},
 title = {The emergence of spin electronics in data storage},
 journal = {Nat. Mater.},
 volume = {6},
 number = {11},
 pages = {813-823},
 year = {2007},
 publisher = {Springer Science and Business Media LLC},
 url = {https://doi.org/10.1038/nmat2024},
 doi = {10.1038/nmat2024},
 source = {Crossref},
 issn = {1476-1122, 1476-4660},
 month = nov,
}

@article{Fert2013skyrmion-racetrack,
 author = {Fert, Albert and Cros, Vincent and Sampaio, João},
 title = {Skyrmions on the track},
 journal = {Nat. Nanotechnol.},
 volume = {8},
 number = {3},
 pages = {152-156},
 year = {2013},
 publisher = {Springer Science and Business Media LLC},
 url = {https://doi.org/10.1038/nnano.2013.29},
 doi = {10.1038/nnano.2013.29},
 source = {Crossref},
 issn = {1748-3387, 1748-3395},
 month = mar,
}

@article{Kiselev2011,
 author = {Kiselev, N S and Bogdanov, A N and Schäfer, R and Rößler, U K},
 title = {Chiral skyrmions in thin magnetic films: {New} objects for magnetic storage technologies?},
 journal = {J. Phys. D: Appl. Phys.},
 volume = {44},
 number = {39},
 pages = {392001},
 url = {https://doi.org/10.1088/0022-3727/44/39/392001},
 year = {2011},
 doi = {10.1088/0022-3727/44/39/392001},
 source = {Crossref},
 publisher = {IOP Publishing},
 issn = {0022-3727, 1361-6463},
 month = sep,
}

@article{Stiles2013DMIvsA,
 author = {Kim, Kyoung-Whan and Lee, Hyun-Woo and Lee, Kyung-Jin and Stiles, M.D.},
 title = {Chirality from Interfacial Spin-Orbit Coupling Effects in Magnetic Bilayers},
 journal = {Phys. Rev. Lett.},
 volume = {111},
 issue = {21},
 pages = {216601},
 numpages = {5},
 year = {2013},
 month = nov,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.111.216601},
 url = {https://doi.org/10.1103/physrevlett.111.216601},
 number = {21},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
}

@article{Tserkovnyak2008review,
 author = {Tserkovnyak, Yaroslav and Brataas, Arne and Bauer, Gerrit E.W.},
 title = {Theory of current-driven magnetization dynamics in inhomogeneous ferromagnets},
 journal = {J. Magn. Magn. Mater.},
 volume = {320},
 number = {7},
 pages = {1282-1292},
 year = {2008},
 publisher = {Elsevier BV},
 url = {https://doi.org/10.1016/j.jmmm.2007.12.012},
 doi = {10.1016/j.jmmm.2007.12.012},
 source = {Crossref},
 issn = {0304-8853},
 month = apr,
}

@article{Sinova2015review,
 author = {Sinova, Jairo and Valenzuela, Sergio O. and Wunderlich, J. and Back, C.H. and Jungwirth, T.},
 title = {Spin Hall effects},
 journal = {Rev. Mod. Phys.},
 volume = {87},
 issue = {4},
 pages = {1213-1260},
 numpages = {47},
 year = {2015},
 month = oct,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/revmodphys.87.1213},
 url = {https://doi.org/10.1103/revmodphys.87.1213},
 number = {4},
 source = {Crossref},
 issn = {0034-6861, 1539-0756},
}

@article{Gilmore2010anisotropicGDabinitio,
 author = {Gilmore, Keith and Stiles, M.D. and Seib, Jonas and Steiauf, Daniel and Fähnle, Manfred},
 title = {Anisotropic damping of the magnetization dynamics in Ni, Co, and {Fe}},
 journal = {Phys. Rev. B},
 volume = {81},
 issue = {17},
 pages = {174414},
 numpages = {6},
 year = {2010},
 month = may,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.81.174414},
 url = {https://doi.org/10.1103/physrevb.81.174414},
 number = {17},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@article{Safonov2002,
 author = {Safonov, Vladimir L.},
 title = {Tensor form of magnetization damping},
 journal = {J. Appl. Phys.},
 volume = {91},
 number = {10},
 pages = {8653},
 year = {2002},
 doi = {10.1063/1.1448794},
 url = {https://doi.org/10.1063/1.1448794},
 source = {Crossref},
 publisher = {AIP Publishing},
 issn = {0021-8979},
}

@article{Mankovsky2013,
 author = {Mankovsky, S. and Ködderitzsch, D. and Woltersdorf, G. and Ebert, H.},
 title = {First-principles calculation of the {Gilbert} damping parameter via the linear response formalism with application to magnetic transition metals and alloys},
 journal = {Phys. Rev. B},
 volume = {87},
 issue = {1},
 pages = {014430},
 numpages = {11},
 year = {2013},
 month = jan,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.87.014430},
 url = {https://doi.org/10.1103/physrevb.87.014430},
 number = {1},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@article{Chen2018,
 author = {Chen, L. and Mankovsky, S. and Wimmer, S. and Schoen, M.A.W. and Körner, H.S. and Kronseder, M. and Schuh, D. and Bougeard, D. and Ebert, H. and Weiss, D. and Back, C.H.},
 title = {Emergence of anisotropic {Gilbert} damping in ultrathin {Fe} layers on {GaAs(001)}},
 journal = {Nat. Phys.},
 volume = {14},
 number = {5},
 pages = {490-494},
 year = {2018},
 publisher = {Springer Science and Business Media LLC},
 url = {https://doi.org/10.1038/s41567-018-0053-8},
 doi = {10.1038/s41567-018-0053-8},
 source = {Crossref},
 issn = {1745-2473, 1745-2481},
 month = mar,
}

@article{1stLiZhang2004,
 author = {Li, Z. and Zhang, S.},
 title = {Domain-wall dynamics driven by adiabatic spin-transfer torques},
 journal = {Phys. Rev. B},
 volume = {70},
 issue = {2},
 pages = {024417},
 numpages = {10},
 year = {2004},
 month = jul,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.70.024417},
 url = {https://doi.org/10.1103/physrevb.70.024417},
 number = {2},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@article{Thiaville,
 author = {Thiaville, A and Nakatani, Y and Miltat, J and Suzuki, Y},
 title = {Micromagnetic understanding of current-driven domain wall motion in patterned nanowires},
 journal = {Europhys. Lett.},
 volume = {69},
 number = {6},
 pages = {990-996},
 url = {https://doi.org/10.1209/epl/i2004-10452-6},
 year = {2005},
 doi = {10.1209/epl/i2004-10452-6},
 source = {Crossref},
 publisher = {IOP Publishing},
 issn = {0295-5075, 1286-4854},
 month = mar,
}

@article{Kim2012,
 author = {Kim, Kyoung-Whan and Seo, Soo-Man and Ryu, Jisu and Lee, Kyung-Jin and Lee, Hyun-Woo},
 title = {Magnetization dynamics induced by in-plane currents in ultrathin magnetic nanostructures with Rashba spin-orbit coupling},
 journal = {Phys. Rev. B},
 volume = {85},
 issue = {18},
 pages = {180404},
 numpages = {5},
 year = {2012},
 month = may,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.85.180404},
 url = {https://doi.org/10.1103/physrevb.85.180404},
 number = {18},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@article{2ndLiZhang2004,
 author = {Zhang, S. and Li, Z.},
 title = {Roles of Nonequilibrium Conduction Electrons on the Magnetization Dynamics of Ferromagnets},
 journal = {Phys. Rev. Lett.},
 volume = {93},
 issue = {12},
 pages = {127204},
 numpages = {4},
 year = {2004},
 month = sep,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.93.127204},
 url = {https://doi.org/10.1103/physrevlett.93.127204},
 number = {12},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
}

@article{2014Kurebayashi,
 author = {Kurebayashi, H. and Sinova, Jairo and Fang, D. and Irvine, A.C. and Skinner, T.D. and Wunderlich, J. and Novák, V. and Campion, R.P. and Gallagher, B.L. and Vehstedt, E.K. and Zârbo, L.P. and Výborný, K. and Ferguson, A.J. and Jungwirth, T.},
 title = {An antidamping spin--orbit torque originating from the Berry curvature},
 journal = {Nat. Nanotechnol.},
 volume = {9},
 number = {3},
 pages = {211-217},
 year = {2014},
 publisher = {Springer Science and Business Media LLC},
 url = {https://doi.org/10.1038/nnano.2014.15},
 doi = {10.1038/nnano.2014.15},
 source = {Crossref},
 issn = {1748-3387, 1748-3395},
 month = mar,
}

@article{1984BychkovRashba,
 author = {Bychkov, Yu A and Rashba, {\'E} I},
 title = {Properties of a {2D} electron gas with lifted spectral degeneracy},
 journal = {JETP Lett.},
 volume = {39},
 number = {2},
 pages = {78},
 year = {1984},
 url = {http://www.jetpletters.ac.ru/ps/1264/article\_19121.shtml},
}

@article{2016MilletariSHE,
 author = {Milletarì, Mirco and Ferreira, Aires},
 title = {Quantum diagrammatic theory of the extrinsic spin Hall effect in graphene},
 journal = {Phys. Rev. B},
 volume = {94},
 issue = {13},
 pages = {134202},
 numpages = {16},
 year = {2016},
 month = oct,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.94.134202},
 url = {https://doi.org/10.1103/physrevb.94.134202},
 number = {13},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
}

@article{Konig2017,
 author = {König, Elio J. and Levchenko, Alex},
 title = {{Kerr} Effect from Diffractive Skew Scattering in Chiral px$\pm$ipy Superconductors},
 journal = {Phys. Rev. Lett.},
 volume = {118},
 issue = {2},
 pages = {027001},
 numpages = {5},
 year = {2017},
 month = jan,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevlett.118.027001},
 url = {https://doi.org/10.1103/physrevlett.118.027001},
 number = {2},
 source = {Crossref},
 issn = {0031-9007, 1079-7114},
}

@article{Kohno2006,
 author = {Kohno, Hiroshi and Tatara, Gen and Shibata, Junya},
 title = {Microscopic Calculation of Spin Torques in Disordered Ferromagnets},
 journal = {J. Phys. Soc. Jpn.},
 volume = {75},
 number = {11},
 pages = {113706},
 year = {2006},
 doi = {10.1143/jpsj.75.113706},
 source = {Crossref},
 url = {https://doi.org/10.1143/jpsj.75.113706},
 publisher = {Physical Society of Japan},
 issn = {0031-9015, 1347-4073},
 month = nov,
}

@article{Garate2009STT,
 author = {Garate, Ion and Gilmore, K. and Stiles, M.D. and MacDonald, A.H.},
 title = {Nonadiabatic spin-transfer torque in real materials},
 journal = {Phys. Rev. B},
 volume = {79},
 issue = {10},
 pages = {104416},
 numpages = {15},
 year = {2009},
 month = mar,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.79.104416},
 url = {https://doi.org/10.1103/physrevb.79.104416},
 number = {10},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@article{Garate2009GD,
 author = {Garate, Ion and MacDonald, Allan},
 title = {{Gilbert} damping in conducting ferromagnets. {II.} Model tests of the torque-correlation formula},
 journal = {Phys. Rev. B},
 volume = {79},
 issue = {6},
 pages = {064404},
 numpages = {9},
 year = {2009},
 month = feb,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.79.064404},
 url = {https://doi.org/10.1103/physrevb.79.064404},
 number = {6},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@book{Rammer,
 author = {Rammer, Jørgen},
 title = {Quantum Transport Theory},
 year = {2018},
 publisher = {CRC Press},
 address = {New York},
 doi = {10.1201/9780429502835},
 source = {Crossref},
 url = {https://doi.org/10.1201/9780429502835},
 isbn = {9780429502835},
 month = may,
}

@article{Ostr2006,
 author = {Ostrovsky, P.M. and Gornyi, I.V. and Mirlin, A.D.},
 title = {Electron transport in disordered graphene},
 journal = {Phys. Rev. B},
 volume = {74},
 issue = {23},
 pages = {235443},
 numpages = {20},
 year = {2006},
 month = dec,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.74.235443},
 url = {https://doi.org/10.1103/physrevb.74.235443},
 number = {23},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@article{Yuan2018,
 author = {Yuan, H.Y. and Wang, Weiwei and Yung, Man-Hong and Wang, X.R.},
 abstract = {A major challenge in spintronics is to find an efficient means to manipulate antiferromagnet (AFM) states, which are inert relative to a uniform magnetic field, due to the vanishingly-small net magnetization. The question is, how does an AFM response to an inhomogeneous field? Here we address the problem through a complete classification of the magnetic forces on an AFM domain wall (DW), revealing the following physical properties: (i) the tiny net magnetization still responses to the field gradient. (ii) the N\'{\{}e{\}}el order is sensitive to the field difference between two sublattices. (iii) DW energy has a quadratic dependence on the magnetic field due to its noncollinear structure. Remarkably, the first two factors drive DW to the opposite directions in a nanowire, but the third effect tends to push the DW to the high field region. Consequently, the competition among these three forces can be applied to understand the seemingly-contradictory results on AFM motion in literature. Additionally, our results provide a new route for a speedy manipulating AFM DW; our numerical simulation indicated that for a synthetic antiferromagnet, the DW propagating speed can reach tens of kilometers per second, an order of magnitude higher than that driven by an electric current.},
 annote = {Only a{\_}n and a{\_}m},
 doi = {10.1103/physrevb.97.214434},
 file = {:C\:/Users/mikba758/Downloads/Yuan et al. - 2018 - Classification of magnetic forces acting on an antiferromagnetic domain wall.pdf:pdf},
 issn = {2469-9950, 2469-9969},
 journal = {Phys. Rev. B},
 keywords = {doi:10.1103/PhysRevB.97.214434 url:https://doi.org},
 number = {21},
 pages = {1--6},
 publisher = {American Physical Society (APS)},
 title = {Classification of magnetic forces acting on an antiferromagnetic domain wall},
 volume = {97},
 year = {2018},
 source = {Crossref},
 url = {https://doi.org/10.1103/physrevb.97.214434},
 month = jun,
}

@article{Yang2018,
 author = {Yang, Huanhuan and Yuan, H.Y. and Yan, Ming and Zhang, H.W. and Yan, Peng},
 abstract = {We theoretically investigate the dynamics of atomic domain walls (DWs) in antiferromagnets driven by a spin-orbit field. For a DW with the width of a few lattice constants, we identify a Peierls-like pinning effect, with the depinning field exponentially decaying with the DW width, so that a spin-orbit field moderately larger than the threshold can drive the propagation of an atomic DW in a step-wise manner. For a broad DW, the Peierls pinning is negligibly small. However, the external spin-orbit field can induce a fast DW propagation, accompanied by a significant shrinking of its width down to atomic scales. Before stepping into the pinning region, noticeable spin waves are emitted at the tail of the DW. The spin-wave emission event not only broadens the effective width of the DW, but also pushes the DW velocity over the magnonic barrier, which is generally believed to be the relativistic limit of the DW speed. While the existing dynamic theory based on the continuum approximation fails in the atomic scale, we develop an energy conversion theory to interpret the DW dynamics beyond the relativistic limit.},
 archiveprefix = {arXiv},
 arxivid = {1812.09540},
 eprint = {1812.09540},
 file = {:C\:/Users/mikba758/Downloads/Yang et al. - 2018 - Atomic antiferromagnetic domain wall propagation beyond the relativistic limit.pdf:pdf},
 pages = {1--6},
 title = {Atomic antiferromagnetic domain wall propagation beyond the relativistic limit},
 url = {https://doi.org/10.1103/physrevb.100.024407},
 year = {2019},
 doi = {10.1103/physrevb.100.024407},
 number = {2},
 source = {Crossref},
 volume = {100},
 journal = {Phys. Rev. B},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
 month = jul,
}

@article{Kimel2009,
 author = {Kimel, A.V. and Ivanov, B.A. and Pisarev, R.V. and Usachev, P.A. and Kirilyuk, A. and Rasing, Th.},
 abstract = {It is generally accepted that the fastest way to reorient magnetization is through precessional motion in an external magnetic field1, 2, 3, 4, 5, 6, 7. In ferromagnets, the application of a magnetic field instantaneously sets spins in motion and, in contrast to the inertial motion of massive bodies, the magnetization can climb over a potential barrier only during the action of a magnetic-field pulse. Here we demonstrate a fundamentally different scenario of spin switching in antiferromagnets, where the exchange interaction between the spins leads to an inertial behaviour. Although the spin orientation hardly changes during the action of an optically generated strong magnetic-field pulse of 100 fs duration, this pulse transfers sufficient momentum to the spin system to overcome the potential barrier and reorient into a new metastable state, long after the action of the stimulus. Such an inertia-based mechanism of spin switching should offer new opportunities for ultrafast recording and processing of magnetically stored information.},
 doi = {10.1038/nphys1369},
 file = {:C\:/Users/mikba758/Downloads/Kimel et al. - 2009 - Inertia-driven spin switching in antiferromagnets.pdf:pdf},
 issn = {1745-2473, 1745-2481},
 journal = {Nat. Phys.},
 number = {10},
 pages = {727-731},
 publisher = {Springer Science and Business Media LLC},
 title = {Inertia-driven spin switching in antiferromagnets},
 url = {https://doi.org/10.1038/nphys1369},
 volume = {5},
 year = {2009},
 source = {Crossref},
 month = aug,
}

@article{Biaek2018,
 author = {Białek, Marcin and Bréchet, Sylvain and Ansermet, Jean-Philippe},
 abstract = {{\copyright } 2018 IOP Publishing Ltd. Heat-driven magnetization damping, which is a linear function of a temperature gradient, is predicted in antiferromagnets by considering the sublattice dynamics subjected to a heat-driven spin torque. This points to the possibility of achieving spi n torque oscillator behavior. The model is based on the magnetic Seebeck effect acting on sublattices which are exchange coupled. The heat-driven spin torque is estimated and the feasibility of detecting this effect is discussed.},
 doi = {10.1088/1361-6463/aab2f7},
 file = {:C\:/Users/mikba758/Downloads/Bia{\l }ek{\_}2018{\_}J.{\_}Phys.{\_}D{\_}{\_}Appl.{\_}Phys.{\_}51{\_}164001.pdf:pdf},
 issn = {0022-3727, 1361-6463},
 journal = {J. Phys. D: Appl. Phys.},
 keywords = {antiferromagnet,antiferromagnetic resonance,spin caloritronics,spin current,spin torque oscillator},
 number = {16},
 title = {Heat-driven spin torques in antiferromagnets},
 volume = {51},
 year = {2018},
 pages = {164001},
 source = {Crossref},
 url = {https://doi.org/10.1088/1361-6463/aab2f7},
 publisher = {IOP Publishing},
 month = mar,
}

@article{Sokolewicz2019,
 author = {Sokolewicz, Robert J},
 file = {:C\:/Users/mikba758/Downloads/Sokolewicz - 2019 - AFM Dynamics.pdf:pdf},
 number = {8},
 pages = {0--1},
 title = {{AFM Dynamics}},
 year = {2019},
}

@article{Troncoso2019,
 author = {Troncoso, Roberto E. and Rode, Karsten and Stamenov, Plamen and Coey, J. Michael D. and Brataas, Arne},
 abstract = {We show how a charge current through a single antiferromagnetic layer can excite and control self-oscillations. Sustained oscillations with tunable amplitudes and frequencies are possible in a variety of geometries using certain classes of non-centrosymmetric materials that exhibit finite dissipative spin-orbit torque. We compute the steady-state phase diagram as a function of the current and spin-orbit torque magnitude. The anisotropic magnetoresistance causes the conversion of the resulting AF oscillations to a terahertz AC output voltage. These findings provide an attractive and novel route to design terahertz antiferromagnetic spin-orbit torque oscillators in simple single-layer structures.},
 annote = {For oscillators: In this work a{\_}n=a{\_}m, all of 4 Gilbert damping constants are equal.},
 doi = {10.1103/physrevb.99.054433},
 file = {:C\:/Users/mikba758/Downloads/PhysRevB.99.054433.pdf:pdf},
 issn = {2469-9950, 2469-9969},
 journal = {Phys. Rev. B},
 keywords = {doi:10.1103/PhysRevB.99.054433 url:https://doi.org},
 number = {5},
 pages = {1--8},
 publisher = {American Physical Society (APS)},
 title = {Antiferromagnetic single-layer spin-orbit torque oscillators},
 volume = {99},
 year = {2019},
 source = {Crossref},
 url = {https://doi.org/10.1103/physrevb.99.054433},
 month = feb,
}

@article{Session,
 author = {Session, S P Parallel and Pham, T H and Je, S and Vallobra, P and Fache, T and Lacour, D and Malinowski, G and Cyrille, M and Gaudin, G and Boulle, O and Hehn, M and Mangin, S},
 file = {:C\:/Users/mikba758/Downloads/Session et al. - Unknown - SP 9 Spin transport and spin dynamics SP 9 Spin transport and spin dynamics.pdf:pdf},
 pages = {1--28},
 title = {{SP 9 Spin transport and spin dynamics {SP} 9 Spin transport and spin dynamics}},
}

@article{Kamra2017,
 author = {Kamra, Akashdeep and Belzig, Wolfgang},
 abstract = {A combination of novel technological and fundamental physics prospects has sparked a huge interest in pure spin transport in magnets, starting with ferromagnets and spreading to antiferro- and ferrimagnets. We present a theoretical study of spin transport across a ferrimagnet{\$}|{\$}non-magnetic conductor interface, when a magnetic eigenmode is driven into a coherent state. The obtained spin current expression includes intra- as well as cross-sublattice terms, both of which are essential for a quantitative understanding of spin-pumping. The dc current is found to be sensitive to the asymmetry in interfacial coupling between the two sublattice magnetizations and the mobile electrons, especially for antiferromagnets. We further find that the concomitant shot noise provides a useful tool for probing the quasiparticle spin and interfacial coupling.},
 annote = {Authors derived a semiclassical expression for the injected spin current. The obtained spin current expression includes intra- as well as cross-sublattice terms.},
 doi = {10.1103/physrevlett.119.197201},
 file = {:C\:/Users/mikba758/Downloads/Kamra, Belzig - 2017 - Spin Pumping and Shot Noise in Ferrimagnets Bridging Ferro- and Antiferromagnets.pdf:pdf},
 issn = {0031-9007, 1079-7114},
 journal = {Phys. Rev. Lett.},
 number = {19},
 pages = {1--6},
 title = {Spin Pumping and Shot Noise in Ferrimagnets: {Bridging} Ferro- and Antiferromagnets},
 volume = {119},
 year = {2017},
 source = {Crossref},
 url = {https://doi.org/10.1103/physrevlett.119.197201},
 publisher = {American Physical Society (APS)},
 month = nov,
}

@article{Keffer1952,
 author = {Keffer, F. and Kittel, C.},
 title = {Theory of Antiferromagnetic Resonance},
 journal = {Phys. Rev.},
 volume = {85},
 issue = {2},
 pages = {329-337},
 numpages = {0},
 year = {1952},
 month = jan,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrev.85.329},
 url = {https://doi.org/10.1103/physrev.85.329},
 number = {2},
 source = {Crossref},
 issn = {0031-899X},
}

@article{Gomonay2010,
 author = {Gomonay, Helen V. and Loktev, Vadim M.},
 title = {Spin transfer and current-induced switching in antiferromagnets},
 journal = {Phys. Rev. B},
 volume = {81},
 issue = {14},
 pages = {144427},
 numpages = {10},
 year = {2010},
 month = apr,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.81.144427},
 url = {https://doi.org/10.1103/physrevb.81.144427},
 number = {14},
 source = {Crossref},
 issn = {1098-0121, 1550-235X},
}

@article{Simensen2019,
 author = {Simensen, Haakon T. and Kamra, Akashdeep and Troncoso, Roberto E. and Brataas, Arne},
 title = {Magnon decay theory of {Gilbert} damping in metallic antiferromagnets},
 journal = {Phys. Rev. B},
 keywords = {Condensed Matter - Mesoscale and Nanoscale Physics},
 year = {2020},
 month = jan,
 eid = {arXiv:1907.01045},
 pages = {arXiv:1907.01045},
 archiveprefix = {arXiv},
 eprint = {1907.01045},
 primaryclass = {cond-mat.mes-hall},
 adsurl = {https://ui.adsabs.harvard.edu/abs/2019arXiv190701045S},
 adsnote = {Provided by the SAO/NASA Astrophysics Data System},
 doi = {10.1103/physrevb.101.020403},
 number = {2},
 source = {Crossref},
 url = {https://doi.org/10.1103/physrevb.101.020403},
 volume = {101},
 publisher = {American Physical Society (APS)},
 issn = {2469-9950, 2469-9969},
}

@article{Yamane-AFM-STT-2016,
 author = {Yamane, Yuta and Ieda, Jun'ichi and Sinova, Jairo},
 title = {Spin-transfer torques in antiferromagnetic textures: {Efficiency} and quantification method},
 journal = {Phys. Rev. B},
 volume = {94},
 issue = {5},
 pages = {054409},
 numpages = {8},
 year = {2016},
 month = aug,
 publisher = {American Physical Society (APS)},
 doi = {10.1103/physrevb.94.054409},
 url = {https://doi.org/10.1103/physrevb.94.054409},
 number = {5},
 source = {Crossref},
 issn = {2469-9950, 2469-9969},
}

@article{Parkin-race-track-2008,
 author = {Parkin, S.S.P. and Hayashi, M. and Thomas, L.},
 title = {Magnetic Domain-Wall Racetrack Memory},
 volume = {320},
 number = {5873},
 pages = {190-194},
 year = {2008},
 doi = {10.1126/science.1145799},
 publisher = {American Association for the Advancement of Science (AAAS)},
 issn = {0036-8075, 1095-9203},
 url = {https://doi.org/10.1126/science.1145799},
 journal = {Science},
 source = {Crossref},
 month = apr,
}

@article{Parkin-race-track-2015,
 author = {Parkin, Stuart and Yang, See-Hun},
 title = {Memory on the racetrack},
 journal = {Nat. Nanotechnol.},
 volume = {10},
 number = {3},
 pages = {195-198},
 year = {2015},
 publisher = {Springer Science and Business Media LLC},
 url = {https://doi.org/10.1038/nnano.2015.41},
 doi = {10.1038/nnano.2015.41},
 source = {Crossref},
 issn = {1748-3387, 1748-3395},
 month = mar,
}

@article{Parkin2015-750ms,
  title={Domain-wall velocities of up to 750 m s-1 driven by exchange-coupling torque in synthetic antiferromagnets},
  author={Yang, See-Hun and Ryu, Kwang-Su and Parkin, Stuart},
  journal={Nat. Nanotechnol.},
  volume={10},
  number={3},
  pages={221},
  year={2015},
  publisher={Nature Publishing Group},
  URL = {https://www.nature.com/articles/nnano.2014.324}
}