Abstract
The discovery of two-dimensional (2D) magnetic van der Waals (vdW) materials has flourished an endeavor for fundamental problems as well as potential applications in computing, sensing and storage technologies. Of particular interest are antiferromagnets, which due to their intrinsic exchange coupling show several advantages in relation to ferromagnets such as robustness against external magnetic perturbations. Here we show that, despite of this cornerstone, the magnetic domains of recently discovered 2D vdW MnPS3 antiferromagnet can be controlled via magnetic fields and electric currents. We achieve ultrafast domain-wall dynamics with velocities up to ~3000 m s−1 within a relativistic kinematic. Lorentz contraction and emission of spin-waves in the terahertz gap are observed with dependence on the edge termination of the layers. Our results indicate that the implementation of 2D antiferromagnets in real applications can be further controlled through edge engineering which sets functional characteristics for ultrathin device platforms with relativistic features.
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Introduction
The emergence of magnetism in 2D vdW materials has opened exciting avenues in the exploration of spin-based applications at the ultimate level of few-atom-thick layers. Remarkable properties including giant tunneling magnetoresistance1,2,3 and layer stacking dependent magnetic phase4,5 have recently been demonstrated. Even though these studies show that rich physical phenomena can be observed in 2D ferromagnets6,7,8,9, the dynamics of domain walls which determine whether such compounds can be effectively implemented in real-life device platforms remains elusive. Very few reports have shed some light on the intriguing behavior of magnetic domains10,11 and their walls12 in ferromagnetic layered materials. The scenario is even less clear for 2D antiferromagnets where the antiferromagnetic exchange coupling between spins adds a level of complexity in terms of the manipulation of the magnetic moments by conventional techniques as zero net magnetization is obtained13. Indeed, recent measurements using tunneling magnetoresistance, a common approach for ferromagnetic materials, unveiled that antiferromagnetic correlations persist down to the level of individual monolayers of MnPS314. This result suggests that yet unexplored ingredients at low-dimensionality play an important role in the detection and manipulation of the antiferromagnetic order in 2D vdW compounds. Moreover, how domain walls in MnPS3 behave and can be controlled externally in functional devices for practical applications are still open questions.
By using correlated first-principles methods, including Hubbard U corrections, large scale Monte Carlo and Landau–Lifshitz–Gilbert equation techniques, we report that electrical currents and, unexpectedly, magnetic fields can move domain walls in monolayer MnPS3 at low-temperatures achieving fast velocities within the km s−1 limit. While bulk antiferromagnetic compounds are insensitive to magnetic fields, the interplay between low-dimensionality and edge-type offers control over domain wall dynamics via an initially unthinkable external parameter. In configurations where the layer terminates with either a zigzag array of Mn atoms or dangling bonds, the domain walls are controllable via both currents and magnetic fields at a broad range of magnitudes. For configurations where the edge atoms assume an armchair configuration, the domain wall appears pinned and no motion is observed irrespective of the field intensity or current density applied. Our results indicate a rich variety of possibilities depending on the edge roughness and introduce the layer termination as one of the determinant factors for integration of 2D antiferromagnets in domain-wall-based applications.
Results
Spin dynamics on monolayer MnPS3
We firstly investigate how magnetic domains are formed in monolayer MnPS3 through simulating the zero-field-cooling process for a large square flake of 0.3 μm × 0.3 μm using atomistic spin dynamics which incorporate micro-scale (several Å’s) and macro-scale (μm-level) underlying details (see full set of details in Supplementary Notes 1–6). The system is thermally equilibrated above the Curie temperature at 80 K and then linearly cooled to 0 K in a simulated time of 4.0 ns as shown in Fig. 1 and Supplementary Movies S1 and S2. The time evolution of the easy-axis component of the magnetization Sz is used to display the nucleation of the magnetic domains at different temperatures and magnetic fields. While domain walls appeared at zero field with a large extension over the simulation area (Fig. 1a–e), an external field can flush out any domains resulting in a homogeneous magnetization after 2 ns (Fig. 1f–j). We also observed that some simulations at zero field ended up in the formation of a monodomain throughout the surface. This suggests that antiferromagnetic domains may not be intrinsically stable in MnPS3 similarly as in ferromagnetic layered materials, e.g., CrI312. The metastability of the domains prevents the wall profiles from reaching a truly ground-state configuration as they initially appear winded at 0 K (Fig. 1d). Undertaking the rendering of the domain wall at different time frames (Supplementary Fig. 10), we noticed that several nodes of a few lattice sites in diameter are created but incidentally evolved to an unwound state (Fig. 1e). A close look reveals a continuous rotation of the spins over the extension of the wall pushing the nodes out of the domain wall profile (Supplementary Movie S3). Such repulsive interactions between nodes can extend as long as ~95 nm along the wall which is more that two order of magnitudes larger than the thickness (0.8 nm15) of the monolayer MnPS3. At longer times, the domain wall reaches stability and does not show any sudden variations on the spin configurations.
To determine whether the interplay between metastability and the high magnetic anisotropy of MnPS3 could give additional features to the domain walls, we analyze the local behavior of the spins in the domain wall (Fig. 2). We notice that as the spins rotate from one magnetic domain to another they tend to align with the zig-zag crystallographic direction displaying an angle of ϕ = 64.02o (Fig. 2a, b). The magnitude of ϕ slightly depends on the starting conditions of the simulations having not effect on the domain wall dynamics. The chirality does not systematically vary with magnetic field or temperature, although elevated temperatures lead to more magnetization fluctuations that can increase the appearance of different chiralities. Moreover, 2D magnetic materials seem to exhibit polychiral domain walls of Néel, Bloch and hybrid character as previously demonstrated12.
The projections of the total magnetization at the wall over the out-of-plane (Sz) and in-plane (Sx, Sy) components show sizeable magnitudes of Sy and Sx as the spins transition from one domain to another despite the easy-axis anisotropy along of Sz (Fig. 2c, d). This indicates a domain wall of hybrid characteristics rather than one of Bloch and Néel type (Fig. 2e, f). We can extract the domain wall width σx,y,z by fitting the different components of the magnetization (Sx, Sy, Sz) to standard equations16 of the form:
where j0 and z0 are the domain wall positions at in-plane and out-of-plane coordinates, respectively. The domain wall widths are within the range of σx,y,z = 3.40–3.50 nm. Such small widths are commonly observed in permanent magnetic materials16 due to their exceptionally high magnetic anisotropy such as Nd2Fe14B (3.9 nm), SmCo5 (2.6 nm), CoPt (4.5 nm) and Mn overlayers on Fe(001) (4.55 nm)17. In these systems, magnetic domains are energetically stable after zero-field cooling due to long-range dipole interactions which were also checked in our study resulting in no modifications of the results. Therefore, MnPS3 reunites characteristics from soft-magnets (large area uniform magnetization) and hard-magnets (large magnetic anisotropy, narrow domain walls) within the same material.
Current-driven domain wall dynamics
An outstanding question raised by these hybrid features is whether the domain walls can be manipulated by external excitations such as electrical currents or magnetic fields. It is well known that antiferromagnets are insensitive to magnetic fields but are rather controllable through currents particularly in high-anisotropy materials13,18. However, the low dimensionality together with the underlying symmetry of the honeycomb structure may lead to features on the dynamics of domain walls not yet observed in bulk antiferromagnets. To investigate this we simulate the spin-transfer torque (STT) induced by spin-polarized currents and the effect of magnetic fields on a large nano-flake of monolayer MnPS3 of dimensions of 300 nm × 50 nm (see Supplementary Note 9 for details). This setup is similar as those used in magnetic wires used in racetrack platforms19,20, which allows its rapid implementation on ongoing investigations. Other mechanisms, such as spin-Hall effect (SHE) induced spin-orbit torque (SOT) were not considered. Since the domain wall motion is mainly driven by STT as the local magnetization textures cause a direct change of angular momentum of the incoming spin-polarized current inducing the magnetization to move. For completeness, we include adiabatic and non-adiabatic contributions to the STT (Supplementary Note 9). The domain wall is initially stabilized from one-atom-thick wall which broadens and develops a profile during the thermalization over a simulation time of 0.5 ns. The finite width of the nanowire assists in the formation of the domain walls. The system is then allowed to evolve for longer times (~2 ns) to ensure that no changes are observed in the system close to the end of the dynamics.
Surprisingly, both electric currents and magnetic fields are able to induce the motion of domain walls in the antiferromagnetic MnPS3 resulting in a broad range of velocities (Figs. 3 and 4). For current-induced domain wall motion, wall velocities up to v = 3000 m s−1 are seen at a maximum current density of j = 80 × 109 A cm−2 (Fig. 3a, b). At such large values of j, we observe primarily two regimes that are characterized by different dependences of v with j. For j ≤ 30 × 109 A cm−2 (Fig. 3a) a linear dependence is noticed which can be described by a one-dimensional model (Supplementary Note 10) as:
where \({C}_{c}=\frac{{\mu }_{B}\sigma }{2\alpha e{m}_{s}{t}_{z}}{\theta }_{{{{\rm{SH}}}}}\), with μb the Bohr magneton, σ the domain wall width, θSH the spin Hall angle, α the Gilbert damping parameter, e the electron charge, ms the modulus of the magnetization per lattice, and tz the layer thickness. Eq. (3) is consistent with adiabatic spin-transfer mechanisms in thin antiferromagnets13,18,21 where the conduction electrons from the current transfer angular momentum to the spins of the wall which keeps its coherence through a steady motion (Fig. 4a, b and Supplementary Movie S4). The value of Cc = 67.11 × 10−13m3C−1 extracted from our simulation data helps to find other parameters not easily accessible in experiments or from theory, e.g., θSH. The magnitude of θSH determines the conversion efficiency between charge and spin currents, and it is the figure of merit of any spintronic application. Using the definition of Cc (Supplementary Note 10), we can estimate θSH(%) = 0.010 which is comparable to standard heterostructures and metallic interfaces22 but at a much thinner limit. This suggests MnPS3 as a potential layered compound for power-efficient device platforms. For j ≥ 40 × 109 A cm−2 the wall velocities tend to saturate to a maximum magnitude near 3000 m s−1 (Fig. 3a) with a deviation from the linear dependence observed previously (Eq. (3)). This intriguing behavior can be understood in terms of the relativistic kinematics of antiferromagnets13,23. As the wall velocities approach the maximum group velocities (vg1, vg2), which sets the maximum speed for spin interactions into the system, relativistic effects in terms of the Lorentz invariance become more predominant. This is due to the finite inertial mass of the antiferromagnetic domain wall which can be decomposed into spin-waves represented through relativistic wave equations21,23,24. We can extend this idea further in a 2D vdW antiferromagnet by examining the variations of several quantities via special relativity concepts. For instance, the variation of the wall velocities versus current densities can be well analyzed using:
where vg2 is the maximum spin-wave group velocity at one of the branches of the magnon dispersion which corresponds to the speed of light in the system21,24 (Supplementary Note 12). Eq. (4) includes quasi-relativistic corrections21,24 to the linear dependence recorded at low values of the density (Eq. (3)) and can be solved self-consistently in v for each magnitude of j. Strikingly, Eq. (4) provides an accurate description of the wall velocity not only at low magnitudes of the density, where relativistic effects are rather small, but also for j ≥ 40 × 109 A cm−2. At such limit, the domain wall width σ and the domain wall mass MDW shrinks and increases, respectively, exhibiting effects similar to the Lorentz contraction (Fig. 3c, d). These phenomena can be reasoned by (see Supplementary Note 10 for details):
where σo is domain wall width at rest (~3.41 nm), which keeps its magnitude at the low-velocity regime, \(\rho =\frac{1}{{J}_{1NN}{\gamma }^{2}}\) (with J1NN the exchange parameter for the first nearest-neighbors and γ the gyromagnetic ratio), w is the width of the stripe of the material, and tz is the layer thickness. The importance of Eqs. (5) and (6) resides on the additional features provided on the internal domain wall structure as well their complementary aspect on the relativistic effects. There is a sound agreement between the simulation data (Fig. 3c, d) and Eqs. (5)–(6) over a wide range of velocities with minor deviations occurring above 2500 m s−1 due to non-linear spin excitations. It is worth mentioning that at such large wall velocities, spin waves or magnons are emitted throughout the layer with frequencies in the terahertz regime (Fig. 3e, f). These excitations can be found in the wake of the wall forming simultaneously in front and behind the wall motion (see Supplementary Movie S5). Analyzing the variations of Sz over time at different j (Supplementary Fig. 12), we noticed that high currents generated precession of the spins around the easy-axis with their high in-plane projections (Sx, Sy) being transmitted through spin-waves into the system (Fig. 3e, f). This is critical at large values of j where the variation of the position of the domain wall with time results in two velocities before and after the magnons start being excited (Supplementary Fig. 12). This behavior is particularly turbulent at longer times as the wall profile can not be defined any more with the appearance of several vortex, antivortex and spin textures at both edges of the layer and inside the flake (Supplementary Movie S6).
Spin excitation and magnon propagation
To have a thorough understanding of the characteristics of spin excitations on the domain wall dynamics in MnPS3, we have developed an analytical model using linear spin-wave theory25,26 that accounts on the magnon dispersion ε(k) and their group velocities \({v}_{g}({{{\bf{k}}}})=\frac{\partial \varepsilon ({{{\bf{k}}}})}{\partial {{{\bf{k}}}}}\) over the entire Brillouin zone. Supplementary Note 12 provides a full description of the details involved. The maximum spin-wave group velocities (vg1, vg2) that MnPS3 can sustain at different magnon branches (Supplementary Fig. 13) are in the range from vg1 = 2323 m s−1 to vg2 = 3421 m s−1 (Fig. 3a). These magnitudes correspond to the highest velocities at which spin excitations can propagate into the system accordingly to the amount of energy (Supplementary Fig. 13a) transferred through current or field. Moreover, vg1 and vg2 correspond to spin waves propagating in opposite direction in the wake of the domain wall as they follow the symmetry of the magnon dispersion over the Brillouin zone (Supplementary Fig. 13b, c). It is worth mentioning that recent mechanisms in terms of magnon pair emission27 cannot be rule out given the pure relativistic origin of the magnon generation, combination and annihilation. Indeed, there is a good agreement with the numerically calculated wall-velocities where the spin-waves start being emitted into the sheet (~2248 m s−1), and the wall saturates to its maximum speed (~2970 m s−1). The slightly lower values obtained in the simulations relative to vg1 and vg2 are due to the effect of damping on the propagation of domain walls due to the emission of spin-waves. A similar feature has been observed in the past in 3D ferromagnetic28,29 and antiferromagnetic21,30 compounds but the emergence of such phenomena in a 2D vdW antiferromagnet is unforeseen. Additionally, we can estimate a maximum wave frequency (fmax = ℏε/2π) corresponding to vg2 of about 4.03 THz. This value surpasses those measured in the state-of-the-art antiferromagnetic materials such as in MnO31, NiO32,33, DyFeO334, HoFeO335 and heterostructures combining MnF2 and platinum36 by several times. This implies that antiferromagnetic domain walls in MnPS3 can be used as a terahertz source of electric signal at the ultimate limit of a few atoms thick layer.
Field-driven domain wall dynamics
Remarkably, the application of a magnetic field results in a very counter-intuitive behavior as the domain wall moves with velocities as high as ~1500 m s−1 (Fig. 3g, h and Supplementary Note 13 for additional discussions). We can fit most of the field-induced domain wall dynamics for B ≤ 20 T with:
with a linear regression coefficient of R2 = 0.9996. The motion is steady, keeping the wall shape throughout the motion. We observe however that both the domain wall width and the domain wall mass change their magnitudes in opposite trend as that observed in the current-driven domain wall dynamics (Supplementary Fig. 15). We attribute this difference to the distinct operation of the external stimulus on the domain wall. In the current-driven case, the action is tightly focused at the center of the wall, where the angular change in neighboring spins is the largest. For large currents the wall is not able to fully relax its spin profile leading to a contraction in the wall width as observed in the atomistic simulations. From a more theoretical standpoint, however, the domain-wall contraction is a relativistic effect due to the invariance of the antiferromagnetic Lagrangian21,24,27. Both views are complementary and provide a thorough explanation of the high-speed phenomena observed on MnPS3.
In contrast, the magnetic field acts across the whole wall and tends to strengthen the spin flop (SF) state, which in turn leads to an increase in the domain wall width with increasing field strength (Supplementary Fig. 15a). This effect compensates any relativistic effects that might be present during the field-driven domain wall (Supplementary Fig. 15b). Wider domain walls naturally have lower mass as they are easier to move until SF states are achieved for fields above 22 T. In addition, some curvature is formed as the wall moves with its starting points from the terminations of the sheet parallel to the wall movement (Fig. 4c and Supplementary Movie 7). The spins around one edge move in advance relative to those at the middle of the system and at the opposite edge creating a curved wall during the motion (see detailed features in Supplementary Movie 8). The domain wall width however suffers negligible modification within this profile (~0.4%) once the curvature is generated. Such deviation from the planar wall shape has been reported in hetero-interfaces formed by NiFe/FeMn bilayers37 but not yet in a monolayer of a 2D vdW antiferromagnet. This indicates a direct relation between domain-wall motion and the material geometry via edge roughness similarly as in magnetic wires38. A close look unveils that the type of edge plays a pivotal role in the domain wall dynamics induced by both magnetic fields and electric currents. Sheets terminated with edge atoms in zig-zag (ZZ) and dangling-bond (DB) configurations (Fig. 4d) in any combination (e.g., ZZ-ZZ, ZZ-DB, DB-DB) can have their domain walls manipulated by currents. Nevertheless, only domain wall in layers with dissimilar edges (e.g., ZZ-DB) can be controlled by magnetic fields. Borders formed by atoms in the armchair (ARM) configuration remain inert irrespective of the stimulus applied (Supplementary Fig. 16). An overall summary is shown in Table 1 with all considered possibilities for edges and driving forces. Intriguingly, ARM edges under applied currents show a short displacement of the domain wall at earlier stages of the dynamics (~0.07 ns) but rapidly stabilizes to a constant position at longer times. As the current flows through the wall, the spins feel the torque induced by the spin-polarized electrons but rather than reorient the spins to follow the current direction, the spins at the wall precess around the easy-axis with no motion of the domain-wall. This mechanism is shown in details in Supplementary Movies S9 and S10. The ARM edge in this case works as an effective pinning barrier for domain-wall propagation. We also noticed that there is no spin-wave emission as the domain is pined at the edges. The fluctuations of the Sx and Sy projections outside the wall are negligible in magnitude (~10−10 a.u.) which are more numerical than physical. Moreover, these negligible oscillations were random and not collective (not coordinated among different atoms). Only when the DW moves throughout the system, the emission of spin waves occurred as showed before.
Edge-mediated domain wall dynamics under magnetic fields
The control of the domain-wall motion in an antiferromagnetic material via magnetic fields creates a playground in the investigation of the role of edges on 2D magnetic materials. The fundamental ingredient that enables such phenomena is based on the underlying magnetic sublattices (e.g., A or B) composing the honeycomb structure (Fig. 5a–c). Despite the border considered, for edge atoms residing at different sublattices the magnetic field induces a torque at each sublattice that mutually compensates each other generating no net displacement of the domain-wall (Supplementary Movie S11). For edge atoms at the same sublattice the effect is additive inducing the translation of the wall. Indeed, we can further confirm this mechanism analyzing the spin interactions present in the system on a basis of a generalized XXZ Heisenberg Hamiltonian in the form of:
where Ji,j is the bilinear exchange interactions between spins Si and Sj at sites i and j, λij is the anisotropic exchange, D is the on-site magnetic anisotropy and Bi is the external magnetic field applied along the easy-axis (e.g., Bz). We only include bilinear exchange terms in Eq. (8) since biquadratic exchange interactions are negligible in MnPS339. We considered pair-wise interactions in 〈i, j〉 up to the third nearest neighbors (3NN) (Supplementary Table 1). All parameters are calculated using strongly correlated density functional theory based on Hubbard-U methods. Supplementary Notes 1–4 convey the full details of the approaches employed. Eq. (8) is then applied to calculate the spin interactions into the system taking into account any angular variations θ of the spins induced by the field. We determine the stability of the system before and after the application of Bz distinguishing the atoms away from the domain wall from those at the wall (Fig. 6a). Such procedure is instrumental to unveil the influence of the edges on the energetics of the domain-wall dynamics as the atoms at these two spatial regions may respond differently to a magnetic perturbation. In fact, we found that spins that are distanced from the domain-wall (i.e., spin-up for θ = 0, and spin-down for θ = 180o) do not suffer any angular variation with Bz as the layer reached an additional ground-state. Nevertheless, for spins at the domain-wall the ground-state under a finite field (Bz ≠ 0) is obtained at a value of θ different to that at Bz = 0 (Fig. 6b, c). This indicates that the wall spins tend to rotate under magnetic fields and the effect is particularly strong for atoms at the edges. The variations in energy −ΔE show that when the two edges are similar (Fig. 6b) two different sublattices will be localized at the borders which will respond likewise generating similar variation of energies. As the atoms at the edges are more uncoordinated relative to those in the bulk of the system, they gain more energy from aligning with Bz which allows the spins to rotate more freely but in opposite direction compensating any displacement of the domain-wall. The scenario is completely different when the atoms at the edges belong to the same sublattice such as in a ZZ-DB layer (Fig. 6c). In this case, −ΔE has a larger variation at the DB edge due to the lesser coordination with neighboring atoms and consequently less exchange energy. This results in a more prompt rotation of the spins at the DB edge than that at the ZZ edge dragging the wall slightly ahead with the field (Supplementary Movie S8). Even though our analysis has been applied for MnPS3 it should be universal for any antiferromagnetic layered material with a honeycomb lattice.
Discussion
One of the implications for having uncompensated spins at the edges selectively controlling domain-wall motion in 2D vdW antiferromagnets is that depending how the layer is oriented in a device-platform we can have many possibilities to induce domain wall dynamics. By engineering the type of edges in MnPS3 we can either induce a fast domain-wall dynamics through both current and magnetic fields, or no motion whatsoever via geometrical constrictions. Our findings also indicate that 2D layered antiferromagnets would not be invisible to common magnetic probes. Indeed, the recent experimental demonstration of field-dependent tunneling magneto resistance observed in MnPS314 is a substantial evidence that a net magnetization is present into the system, which following our findings is due to edges. Such characteristic could be critical to generate localized magnetic moments that would allow further control of magnetic processes involving interfaces and heterostructures. In this case the antiferromagnetic layer can play a more active role in magnetic structures rather than induce exchange bias in an adjacent ferromagnetic layer13. We foreseen that compounds that would have edges with similar sub-lattices would develop a response to a magnetic field despite their atomic composition.
On the experimental realization of our theoretical results, several approaches may be borrowed from those already established and successfully applied to control and characterize edges in other 2D materials, such as in graphene40,41 and transition metal dichalcogenides42,43. The recent demonstration of etching process along certain crystallographic axes allows to obtain atomically sharp edges and exclusively of one type42. This opens the prospects of developments of such method in 2D vdW magnets taking into account the stability, degradation and the magnetic properties of the systems. For practical implementations, metallic substrates (e.g., Pt, Ta, W) can be used to induce spin-transfer torque on MnPS3 as recently demonstrated for insulating oxide layers44. Indeed, the range of domain-wall velocities predicted in our simulations at low densities (e.g., ~100 m s−1 at ~108 A cm−2) and fields of <0.8 T can be achieved at similar setup44 (Supplementary Fig. 18). Such speeds are sufficient to operate domain-wall technologies (e.g., racetracks) at clock rates competitive with existing materials in similar current densities, i.e., permalloy nanowires19,20. The field-driven domain wall velocities calculated are also at the same magnitude as those found in magnetic semiconducting thin films, e.g., (Ga,Mn)(As,P) (4–24 m s−1 within 25–125 mT)45,46 and TbFe (~4.72 m s−1 at 382 mT) films45. The insulating character of MnPS3 may also not be considered as an disadvantage relative to metallic thin films where low heating dissipation and low power consumption can be explored as recently demonstrated for magnetic insulators44,47. In addition, the low domain wall mass within 0.55–0.75 × 10−26 kg and the narrow domain wall width in 3.4–2.5 nm suggest fast logic on memory devices. The former is at least 4 order of magnitude smaller than those observed on standard magnetic compounds with much larger width48. This indicates that massless domain walls may be achieved on 2D magnets where transient effects induced by current pulses can be negligible49. This calls for further investigations using the methods developed in our study on different families of 2D vdW magnetic materials. With the rapid integration of magnetic layered materials into device-related applications and the discovery of more compounds with similar characteristics, our predictions set a horizon of possibilities on the investigations of domain wall-mediated 2D antiferromagnetic spintronics.
Methods
Hubbard-corrected ab initio simulations
Ab-initio calculations were performed using Density Functional Theory (DFT) as implemented in the VASP package50,51. Within the generalized gradient approximation (GGA), the Perdew–Burke–Ernzerhof (PBE) exchange-correlation functional was used. No van der Waals interactions were taken into account given that the system of interest is a monolayer. A Hubbard U correction was included through the Dudarev formulation52. The exchange parameter J was fixed as J = 0.9 eV while the U energy was calculated through the linear response method resulting in a magnitude of U = 2.58 eV53,54,55,56. These values of J and U were used in all calculations. Additional details on the DFT calculations, parametrization of the spin Hamiltonian used in the simulations are included in Supplementary Notes 1–4.
Large scale spin dynamics
Macromagnetic quantities such as magnetization, susceptibility or Néel temperature were calculated by atomistic methods previously implemented as described in refs. 12,39 A 50 nm × 50 nm square flake (15580 sites in total) with periodic boundary conditions was utilized for these simulations. Additional details are included in Supplementary Notes 5 and 6.
Data availability
The data that support the findings of this study are available within the paper and its Supplementary Information.
References
Song, T. et al. Giant tunneling magnetoresistance in spin-filter van der waals heterostructures. Science 360, 1214–1218 (2018).
Wang, Z. et al. Very large tunneling magnetoresistance in layered magnetic semiconductor CrI3. Nat. Commun. 9, 2516 (2018).
Klein, D. R. et al. Probing magnetism in 2d van der waals crystalline insulators via electron tunneling. Science 360, 1218–1222 (2018).
Song, T. et al. Switching 2d magnetic states via pressure tuning of layer stacking. Nat. Mater. 18, 1298–1302 (2019).
Chen, W. et al. Direct observation of van der waals stacking–dependent interlayer magnetism. Science 366, 983–987 (2019).
Guguchia, Z. et al. Magnetism in semiconducting molybdenum dichalcogenides. Sci. Adv. 4, eaat3672 (2018).
Macy, J. et al. Magnetic field-induced non-trivial electronic topology in fe3xgete2. Appl. Phys. Rev. 8, 041401 (2021).
Meseguer-Sánchez, J. et al. Coexistence of structural and magnetic phases in van der waals magnet cri3. Nat. Commun. 12, 6265 (2021).
Chen, L. et al. Magnetic field effect on topological spin excitations in cri3. Phys. Rev. X 11, 031047 (2021).
Thiel, L. et al. Probing magnetism in 2d materials at the nanoscale with single-spin microscopy. Science 364, 973–976 (2019).
Zhong, D. et al. Layer-resolved magnetic proximity effect in van der waals heterostructures. Nat. Nanotechnol. 15, 187–191 (2020).
Wahab, D. A. et al. Quantum rescaling, domain metastability, and hybrid domain-walls in 2d cri3 magnets. Adv. Mater. 33, 2004138 (2021).
Baltz, V. et al. Antiferromagnetic spintronics. Rev. Mod. Phys. 90, 015005 (2018).
Long, G. et al. Persistence of magnetism in atomically thin mnps3 crystals. Nano Lett. 20, 2452–2459 (2020).
Long, G. et al. Isolation and characterization of few-layer manganese thiophosphite. ACS Nano 11, 11330–11336 (2017).
Hubert, A. & Schafer, R. Magnetic domains: the analysis of magnetic microstructures (Springer Science and Business Media, 2008).
Schlickum, U., Janke-Gilman, N., Wulfhekel, W. & Kirschner, J. Step-induced frustration of antiferromagnetic order in mn on fe(001). Phys. Rev. Lett. 92, 107203 (2004).
Jungwirth, T., Marti, X., Wadley, P. & Wunderlich, J. Antiferromagnetic spintronics. Nat. Nanotechnol. 11, 231–241 (2016).
Hayashi, M. et al. Current driven domain wall velocities exceeding the spin angular momentum transfer rate in permalloy nanowires. Phys. Rev. Lett. 98, 037204 (2007).
Parkin, S. S. P., Hayashi, M. & Thomas, L. Magnetic domain-wall racetrack memory. Science 320, 190–194 (2008).
Shiino, T. et al. Antiferromagnetic domain wall motion driven by spin-orbit torques. Phys. Rev. Lett. 117, 087203 (2016).
Rojas-Sánchez, J.-C. et al. Spin pumping and inverse spin hall effect in platinum: the essential role of spin-memory loss at metallic interfaces. Phys. Rev. Lett. 112, 106602 (2014).
Haldane, F. D. M. Nonlinear field theory of large-spin heisenberg antiferromagnets: semiclassically quantized solitons of the one-dimensional easy-axis néel state. Phys. Rev. Lett. 50, 1153–1156 (1983).
Kim, S. K., Tserkovnyak, Y. & Tchernyshyov, O. Propulsion of a domain wall in an antiferromagnet by magnons. Phys. Rev. B 90, 104406 (2014).
Oguchi, T. Theory of spin-wave interactions in ferro- and antiferromagnetism. Phys. Rev. 117, 117–123 (1960).
Kubo, R. The spin-wave theory of antiferromagnetics. Phys. Rev. 87, 568–580 (1952).
Tatara, G., Akosa, C. A. & Otxoa de Zuazola, R. M. Magnon pair emission from a relativistic domain wall in antiferromagnets. Phys. Rev. Res. 2, 043226 (2020).
Wieser, R., Vedmedenko, E. Y. & Wiesendanger, R. Domain wall motion damped by the emission of spin waves. Phys. Rev. B 81, 024405 (2010).
Bouzidi, D. & Suhl, H. Motion of a bloch domain wall. Phys. Rev. Lett. 65, 2587–2590 (1990).
Tveten, E. G., Qaiumzadeh, A. & Brataas, A. Antiferromagnetic domain wall motion induced by spin waves. Phys. Rev. Lett. 112, 147204 (2014).
Nishitani, J., Nagashima, T. & Hangyo, M. Terahertz radiation from antiferromagnetic mno excited by optical laser pulses. Appl. Phys. Lett. 103, 081907 (2013).
Kampfrath, T. et al. Coherent terahertz control of antiferromagnetic spin waves. Nat. Photonics 5, 31–34 (2011).
Satoh, T. et al. Spin oscillations in antiferromagnetic nio triggered by circularly polarized light. Phys. Rev. Lett. 105, 077402 (2010).
Kimel, A. V. et al. Ultrafast non-thermal control of magnetization by instantaneous photomagnetic pulses. Nature 435, 655–657 (2005).
Mukai, Y., Hirori, H., Yamamoto, T., Kageyama, H. & Tanaka, K. Antiferromagnetic resonance excitation by terahertz magnetic field resonantly enhanced with split ring resonator. Appl. Phys. Lett. 105, 022410 (2014).
Vaidya, P. et al. Subterahertz spin pumping from an insulating antiferromagnet. Science 368, 160 (2020).
Nikitenko, V. I. et al. Asymmetry in elementary events of magnetization reversal in a ferromagnetic/antiferromagnetic bilayer. Phys. Rev. Lett. 84, 765–768 (2000).
Nakatani, Y., Thiaville, A. & Miltat, J. Faster magnetic walls in rough wires. Nat. Mater. 2, 521–523 (2003).
Kartsev, A., Augustin, M., Evans, R. F. L., Novoselov, K. S. & Santos, E. J. G. Biquadratic exchange interactions in two-dimensional magnets. npj Comput. Mater. 6, 150 (2020).
Baringhaus, J. et al. Exceptional ballistic transport in epitaxial graphene nanoribbons. Nature 506, 349–354 (2014).
Murdock, A. T. et al. Controlling the orientation, edge geometry, and thickness of chemical vapor deposition graphene. ACS Nano 7, 1351–1359 (2013).
Munkhbat, B. et al. Transition metal dichalcogenide metamaterials with atomic precision. Nat. Commun. 11, 4604 (2020).
Lv, R. et al. Transition metal dichalcogenides and beyond: synthesis, properties, and applications of single- and few-layer nanosheets. Acc. Chem. Res. 48, 56–64 (2015).
Vélez, S. et al. High-speed domain wall racetracks in a magnetic insulator. Nat. Commun. 10, 4750 (2019).
Jeudy, V. et al. Universal pinning energy barrier for driven domain walls in thin ferromagnetic films. Phys. Rev. Lett. 117, 057201 (2016).
Thevenard, L. et al. Domain wall propagation in ferromagnetic semiconductors: beyond the one-dimensional model. Phys. Rev. B 83, 245211 (2011).
Caretta, L. et al. Relativistic kinematics of a magnetic soliton. Science 370, 1438–1442 (2020).
Saitoh, E., Miyajima, H., Yamaoka, T. & Tatara, G. Current-induced resonance and mass determination of a single magnetic domain wall. Nature 432, 203–206 (2004).
Vogel, J. et al. Direct observation of massless domain wall dynamics in nanostripes with perpendicular magnetic anisotropy. Phys. Rev. Lett. 108, 247202 (2012).
Kresse, G. & Furthmüller, J. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Phys. Rev. B 54, 11169 (1996).
Kresse, G. & Joubert, D. From ultrasoft pseudopotentials to the projector augmented-wave method. Phys. Rev. B 59, 1758–1775 (1999).
Dudarev, S. L., Botton, G. A., Savrasov, S. Y., Humphreys, C. J. & Sutton, A. P. Electron-energy-loss spectra and the structural stability of nickel oxide: An lsda+u study. Phys. Rev. B 57, 1505–1509 (1998).
Tian, T. et al. Electronic polarizability as the fundamental variable in the dielectric properties of two-dimensional materials. Nano Lett. 20, 841–851 (2020).
Li, L. H., Tian, T., Cai, Q., Shih, C.-J. & Santos, E. J. G. Asymmetric electric field screening in van der waals heterostructures. Nat. Commun. 9, 1271 (2018).
Santos, E. J. G. Carrier-mediated magnetoelectric coupling in functionalized graphene. ACS Nano 7, 9927–9932 (2013).
Hong, J. et al. Intrinsic controllable magnetism of graphene grown on fe. J. Phys. Chem. C. 123, 26870–26876 (2019).
Acknowledgements
R.F.L.E. gratefully acknowledges the financial support of ARCHER UK National Supercomputing Service via the embedded CSE programme (ecse1307). K.S.N. thanks the Ministry of Education (Singapore) through the Research Center of Excellence program (grant EDUN C-33-18-279-V12, I-FIM) for funding support. E.J.G.S. acknowledges computational resources through CIRRUS Tier-2 HPC Service (ec131 Cirrus Project) at EPCC funded by the University of Edinburgh and EPSRC (EP/P020267/1); ARCHER UK National Supercomputing Service (http://www.archer.ac.uk) via Project d429. E.J.G.S. acknowledges the EPSRC Early Career Fellowship (EP/T021578/1) and the University of Edinburgh for funding support.
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E.J.G.S. conceived the idea and supervised the project. I.M.A. performed ab initio and Monte Carlo simulations under the supervision of E.J.G.S. I.M.A. and E.J.G.S. elaborated the analysis and figures. R.F.L.E. implemented the spin-transfer-torque method. E.J.G.S. wrote the paper with inputs from all authors. K.S.N. helped in the analysis and discussions. All authors contributed to this work, read the manuscript, discussed the results, and agreed to the contents of the manuscript.
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Alliati, I.M., Evans, R.F.L., Novoselov, K.S. et al. Relativistic domain-wall dynamics in van der Waals antiferromagnet MnPS3. npj Comput Mater 8, 3 (2022). https://doi.org/10.1038/s41524-021-00683-6
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DOI: https://doi.org/10.1038/s41524-021-00683-6
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