Abstract
In contrast to the current research on two-dimensional (2D) materials, which is mainly focused on graphene and transition metal dichalcogenide-like structures, studies on 2D transition metal oxides are rare. By using ab initio calculations along with Monte Carlo simulations and nonequilibrium Green’s function method, we demonstrate that the transition metal oxide monolayer (ML) of Cr2O3 is an ideal candidate for next-generation spintronics applications. 2D Cr2O3 has honeycomb-kagome lattice, where the Dirac and strongly correlated fermions coexist around the Fermi level. Furthermore, the spin exchange coupling constant shows strong ferromagnetic (FM) interaction between Cr atoms. Cr2O3 ML has a robust half-metallic behavior with a large spin gap of ~3.9 eV and adequate Curie temperature. Interestingly, an intrinsic Ising FM characteristic is observed with a giant perpendicular magnetocrystalline anisotropy energy of ~0.9 meV. Most remarkably, nonequilibrium Green’s function calculations reveal that the Cr2O3 ML exhibits an excellent spin filtering effect.
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Introduction
A tremendous amount of research attention is currently focused on nanomaterials because of their remarkable physical properties and diverse technological applications1. While there have been significant progress in the field of two-dimensional (2D) materials displaying a broad range of electronic and optical properties2, most of these materials are intrinsically nonmagnetic, thus hindering their application to spintronics3. Recent experimental discoveries of ferromagnetic (FM) 2D layers have demonstrated the cleavage of CrI3 (ref. 4) and Cr2Ge2Te6 (ref. 5) single crystals that possess a FM order even in the monolayer (ML). Moreover, numerous room-temperature FM thin films containing 3d transition metals, such as VSe2 (ref. 6) and δ-FeOOH7 have been synthesized on van der Waals substrates. These recent experimental recognitions of intrinsic magnetism in 2D materials have instigated the search for 2D magnetic materials that exhibit long-range ferromagnetism.
Spintronics is one of the most promising fields in condensed matter physics owing to the expectation of various applications of innovative technologies by utilizing the spin degree of freedom8. In the field of spintronics, half-metallic materials have many advantages because one spin channel is conductive, while the other is insulating9. This results in a 100% spin polarization and giant magnetoresistance, which are essential quantities for spintronics. Various materials are known to be half-metallic, but most of them are conventional bulk systems. 2D layers show many peculiar physical properties because of great modifications in their electronic structures at low dimension. Increase in the thickness as compared to ML has a significant effect on its properties, such as change in magnetic ordering, bandgap dependency, and metal–insulator transition. In addition, numerous quantum phases including the quantum spin and quantum anomalous Hall effect etc. are expected to be discovered in 2D layers and their heterostructures. Due to the high demand for next-generation nanoscale spintronic devices, it is necessary to develop 2D half-metallic materials.
In contrast to the current research, which is mainly focused on the 2D graphene and transition metal dichalcogenide-like structures10,11,12,13,14, very few atomically thin metal oxides15,16,17 and hydroxides18 have been synthesized to date. Experimental study of 2D magnetic layers shows the Cr-based layers have FM state with large spin magnetic moment (≥3 μB)19. Moreover, experimental fabrication of the ultrathin Cr2O3 nanosheets by rapid thermal annealing20 that suggests the viability of synthesizing 2D Cr2O3 motivates us to explore the stability, electronic, and magnetic properties of Cr2O3 ML. Ab initio calculations demonstrate that the half-metallic Cr2O3 ML satisfies the key factors for next-generation spintronics applications, such as large spin gap, magnetocrystalline anisotropy energy (MAE), and high Curie temperature (Tc). The exceptionally large spin gap of ~3.9 eV and its distinct honeycomb-kagome structure differentiate Cr2O3 ML from the recent theoretical prediction of 2D magnetic materials21,22,23,24,25. Cr2O3 ML displays not only an adequate Tc (185 K), but also a giant perpendicular MAE as compared to experimentally realized 2D layers4,5,26,27. Our results show that the 2D Cr2O3 ML exhibits an intrinsic Ising ferromagnetism and excellent spin filtering effect.
Results and discussion
Structural stability
The Cr2O3 ML is a honeycomb-kagome lattice (as shown in Fig. 1a), in which the O atoms form a kagome lattice, while the Cr atoms bonding with the O atoms form a hexagonal lattice. This honeycomb-kagome structure may lead to exotic magnetic properties different from the case of the pure kagome lattice. The stability of Cr2O3 ML was evaluated from the formation energy
where E(Cr2O3) is the total energy of Cr2O3 ML, E(Cr) is the energy of a Cr atom in the stable bulk (bcc-Cr) crystal, and μ(O2) is the chemical potential of oxygen gas. The formation energy of Cr2O3 ML is –8.75 eV atom−1, which is comparable to the graphene (–8.66 eV atom−1)28. The formation energy shows that the Cr2O3 ML is a strongly bonded planar network and can be prepared via well-established soft chemical routes.
The dynamical properties of the Cr2O3 ML were evaluated by phonon dispersion calculations, as shown in Fig. 1b. Very low-frequency phonon modes mostly originate from Cr atoms, while we observe O dominated phonon modes at 5 THz. The phonon band structure shows extremely small dispersion for these modes, thus indicating that O dominated frequency modes are completely localized. On the other hand, phonon band structures show that high optical modes (~18 THz) are also dominated by O atoms. The phonon band dispersions have no imaginary frequency modes, thus demonstrating that Cr2O3 ML is kinetically stable. In addition, the thermal stability of the Cr2O3 ML was assessed by performing ab initio molecular dynamics (MD) simulations at room temperature. Figure 1c, d shows snapshots of the Cr2O3 ML at the end of 5 ps at 300 K. Note that the structure of the Cr2O3 ML is intact, and all of the atomic bonds survive at room temperature. Nonetheless, the structure displays a weak out-of-plane rippling. This finding indicates that the Cr2O3 ML can exist under realistic experimental conditions.
Magnetic properties and spin exchange coupling
The next issue to investigate is the magnetic property of the 2D Cr2O3 ML, with consideration of both the FM and antiferromagnetic (AFM) couplings between nearest-neighbor Cr atoms (AFM3 configuration in Fig. 2). To verify the magnetic state of Cr2O3 ML, various exchange-correlation functionals were used, including conventional local density approximation (LDA)29, generalized gradient approximation (GGA-PBE)30, the Hubbard on-site Coulomb parameter (U)31 of 2 eV together with J = 0.7 eV for Cr atoms to account for strong electronic correlations, and the recently developed strongly constrained and appropriately normed meta-GGA functional32. Table 1 lists the calculated energy differences between FM and AFM configurations. It is worth mentioning that all functionals show the stable FM state, as well as the same spin moment, so from this point forward, we used the GGA-PBE functional for our calculations. Figure 2a presents the spin density, ρ↑ − ρ↓, of the Cr2O3 ML, suggesting that the magnetism originates entirely from FM coupled Cr atoms, while the O atoms have an opposite spin with a very small magnetic moment of 0.1 μB.
Next, we calculated the spin exchange coupling for Cr2O3 ML. As a matter of fact, applying the isotropic Heisenberg model to a 2D FM system is against the Mermin–Wagner theorem, which claims the absence of long-range magnetic ordering at nonzero temperature26. Thus, the 2D Ising model is used to describe the spin coupling. Cr atoms are the main magnetic building block in Cr2O3 ML. Cr ions in the 2D layer have the oxidation state of +3 and are expected to give the spin S = 3/2. This has been confirmed by the calculations of magnetic moment where each Cr carrying a spin magnetic moment of 3 μB. The magnetic moments localized on each Cr atom (local spins \(S_{i,j}^z\) = 3/2) can be explained with S = 3/2 spin Hamiltonian. For this purpose, we considered a 2 × 2 cell with four different spin configurations, as shown in Fig. 2b–e. To check the effect of supercell size on magnetic exchange coupling, we have also calculated a 4 × 4 cell. With the energies of four ordered spin states, three exchange constants, J1, J2, and J3, between the first, second, and third nearest neighbors, respectively, were determined. The magnetic exchange coupling constants were calculated by
and
The calculated values of exchange constants J1, J2, and J3 are listed in Table 2, where J > 0 indicates FM coupling, while J < 0 describes AFM one. All functionals display the FM interaction between first nearest neighbors and J1 strongly dominates over others in all functionals except GGA + U. Furthermore, all functionals show the positive ΔJ(ΔJ = J1 + J2 +J3) value, which indicates the stable FM state of Cr2O3 ML. The values of exchange coupling in the larger cell are comparable with the smaller cell that indicates the 2 × 2 cell is enough to describe the magnetic exchange coupling in 2D Cr2O3 ML.
Electronic properties: band structure and density of states
We now discuss the electronic properties of Cr2O3 ML, which are important in terms of their application to electronic devices. GGA-PBE functional was used to calculate the band structure and partial density of states (DOS). Figure 3a shows that Cr2O3 ML is a half-metallic 2D material with a large spin gap of ~3.9 eV at Γ point. We projected the band structure for Cr2O3 ML onto the atomic d orbitals of Cr shown in Fig. 3b, c and the p orbitals of O in Fig. 3d, e. Interestingly, typical kagome band characteristics are observed in the electronic band structure. Below the Fermi level, linearly dispersive band forms a Dirac point at the high symmetry K point and the corresponding two flat bands quadratically contact with the Dirac bands at the Γ point, which are located above and below the Fermi level as marked by circles shown in Fig. 3b. The same feature has been detected in other 2D kagome structures33. The single-spin Dirac points below the Fermi level arise from the hybridization of the out-of-plane Cr (dxz, dyz) states with slight contributions from the O (dz) states, while the Dirac point above the Fermi level is composed of in-plane Cr (dxy, \(d_{x^2 - y^2}\)) and O (pxy) orbitals, as shown in Fig. 3b, d. The out-of-plane orbitals dxz, dyz, and pz form flat bands below and above the Fermi level. Flat bands are rare and emerge only in a few systems, such as twisted bilayer graphene, kagome lattices, and heavy-fermion compounds34. Since the kinetic energy of electron is quenched in the flat band, thus the out-of-plane orbitals dxz, dyz, and pz orbitals which form flat band have special significance. These out-of-plane orbitals indeed are responsible for the FM state in the Cr2O3 layer, which is explained in detail in the next section.
The magnetic exchange interaction between Cr atoms strongly depends on the electronic structure of Cr2O3 ML. In the case of FM configuration, O atoms also become spin-polarized, while in AFM case they remain nonmagnetic. Thus, O atom plays a vital role in the half-metallic FM state of Cr2O3 ML. No direct exchange coupling is observed between O and Cr states in AFM case and spin-polarized d-states are turned out to be more localized. On the other hand in FM configuration, we find that O(p) and Cr(d) orbitals hybridize a flat band just above the Fermi level, and this flat band degenerates with the conduction states formed by Cr (dxz, dyz) orbitals at Γ point (see Fig. 3). Hence it provides an extra channel for indirect coupling between two neighboring Cr atoms through O atom, which is absent in AFM case. This conduction electron mediates indirect spin–spin coupling between Cr atoms through O atom, which is responsible for the FM state between Cr atoms in Cr2O3 ML. Figure 3f displays the partial DOS of the Cr2O3 ML. The major contribution to the magnetic moment originates from the out-of-plane orbitals \(\left| m \right| = 0(d_{z^2})\) and \(\left| m \right| = \pm 1\left( {d_{xz},d_{yz}} \right).\)
Magnetic anisotropy energy and curie temperature
As described before, the Mermin–Wagner theorem prohibits FM order at finite temperatures in 2D materials with continuous spin symmetries due to divergent contributions from gapless spin waves. In order to lift the restriction of continuous spin symmetry, some amount of MAE is required. Figure 4a shows the angular dependence of the MAE at the spin axis \(\hat s(\phi ,\theta )\), where ϕ is the polar angle which is rotated through the plane of the a and c axis of Cr2O3 ML, and θ is the azimuthal angle. The MAE is defined as the difference in energy between the system with a given \(\hat s(\phi ,\theta )\) and the system with spins parallel (P) to the magnetic easy axis. The easy axis is found to be in the out-of-plane direction and the energy of the system with spins oriented along this direction is set to zero. MAE reaches a maximum value of 0.9 meV at ϕ = 90°, corresponding to an in-plane spin orientation. The value of MAE is significantly higher than bulk transition metals, such as Fe, Co, Ni (1–3 µeV atom−1)35, and the Cr2Ge2Te6 ML (0.4 meV cell−1)26, while it is comparable to the CrI3 ML (1.67 meV cell−1)27. Figure 4b illustrates the in-plane magnetization as the spin axis rotates through ab plane. MAE exhibits a strong dependence on the polar angle ϕ and is independent of the azimuthal angle θ, which is a remarkable characteristic of stable intrinsic Ising ferromagnetism. Figure 4c, d depict the orbital-resolved MAE of Cr(d) and O(p), respectively. Spin–orbit coupling (SOC) allows to calculate the matrix elements ESOC for the angular momentum (l = 1, 2). Following the second-order perturbation theory, the MAE can be approximately determined by matrix elements of the angular momentum operator. The matrix element difference is taken between easy axis [001] and hard axis [100]. Positive and negative values indicate the out-of-plane and in-plane contributions in MAE, respectively. For Cr atoms, the differences of the matrix elements of \(d_{xz} - d_{z^2}\) between in-plane and out-of-plane magnetization show large contribution for out-of-plane magnetization, while the others show negligible. For O atoms, the major matrix element difference of px − py shows negative value, which results in the in-plane magnetization.
For practical spintronics applications, it is necessary to explore the change in magnetism of Cr2O3 ML with respect to temperature. Tc is a critical point at which the FM system becomes paramagnetic, and this is an important parameter to evaluate magnetic properties. We simulated the temperature-dependent magnetization curve of Cr2O3 ML by carrying out Monte Carlo (MC) simulations36. Our model includes the MAE term in the Hamiltonian equation and can be written as
where \(\widehat {m_i}\) and \(\widehat {m_j}\) are the magnetic moments (in μB) at sites i and j, respectively, k2 is the anisotropy constant (MAE per atom), mi is the spin lying along a single preferred axis (known as the easy axis), and J is the exchange parameter. For MC simulations, a 50 × 50 supercell was used to mimic the 2D lattice; this is found to be large enough to minimize the periodic constraints. The MC simulations used 10,000 equilibrations and averaging steps. These MC simulations allow us to calculate variations in the mean magnetization per unit cell with temperature. To validate our method, we have calculated the Tc of CrI3 ML then compared it with the experimental value and the value obtained by the spin-wave theory37. Spin-wave theory gives Tc = 33 K, underestimating the experimental value of 45 K by 20%. In contrast, our calculated value 46 K is in perfect agreement with the experimental value, proving the reliability of our method. The calculated mean magnetization as a function of temperature for Cr2O3 ML is illustrated in Fig. 5. Note that the magnetization decreases to 0.77 μB at 100 K and the paramagnetic state is found at the temperature of ~185 K. The value of Tc is significantly higher than those of the Cr2Ge2Te6 (30 K)5, CrI3 (45 K)4, and even Fe3GeTe2 (130 K)38 layers.
Nonequilibrium Green’s function transport properties
Lastly, to explore the spin-filtering effect at magnetic domains in half-metallic Cr2O3 ML, we calculated the spin transport properties at zero bias voltage of the device based on Cr2O3 ML (inset in Fig. 6d). The corresponding position-dependent distributions of DOS for the Cr2O3 electrode are shown in Fig. 6a, b. It is clear from Fig. 6a that the majority spin dominates the whole energy range. On the other hand, the minority spin is concentrated away from the Fermi level in Fig. 6b. We compared the transport properties between the P and antiparallel (AP) magnetization configurations, where the spin orientations of Cr atoms in the left and right electrodes are the same and inverse, respectively. Spin-dependent conductance for P and AP configurations at zero bias can be seen in Fig. 6c, d. P configuration of the two-probe systems (as shown in Fig. 6c) is periodic with translational symmetry and the conductance for each spin takes a step form given by the number of transport channels times the conductance quantum G0 = e2/h. The spin-up current is surpassed while the spin-down current is completely inhibited. In the AP configuration, as shown in Fig. 6d, the conductance spectra show no transport channel over a wide range of energy, and extremely small conductance is found away from the Fermi level in both spin-up and spin-down channels due to the similarity of the energy bands of opposite spins. Thus, both the spin-up and spin-down conductances in the AP configuration are ignorable compared to the spin-down conductance in the P configuration. Our findings demonstrate that the perfect spin filtering can be achieved in a device based on Cr2O3 ML in a wide energy range around the Fermi level.
Motivated by the experimental observation of 2D Ising FM in MLs, we used first-principle calculations to systemically investigate the electronic and magnetic properties of Cr2O3 ML. We demonstrated that the honeycomb-kagome lattice of Cr2O3 ML is thermodynamically stable at room temperature. Cr2O3 ML has a honeycomb-kagome structure characterized by a kagome band with an unusually large gap in one spin channel. MAE exhibits a strong dependence on the polar angle ϕ and is independent of the azimuthal angle θ, which is the characteristic of a stable intrinsic Ising ferromagnetism. Calculations of the magnetic anisotropy revealed a giant MAE of ~0.9 meV. The MC simulations demonstrated that the Tc of the Cr2O3 ML is estimated to be 185 K. We also investigated the spin transport properties by using the nonequilibrium Green’s function method, and found that the Cr2O3 ML exhibits an excellent spin filtering. We anticipate that our work will stimulate experimental studies to validate and extend our findings.
Methods
First-principles calculations details
The structural, electronic, and magnetic properties were calculated by using the Vienna ab initio simulation package (VASP)39,40. The interaction between valence electrons and ionic cores was described within the framework of the projector augmented wave method41. The energy cutoff for the plane wave basis expansion was set to 500 eV. The ground state optimized lattice constants of the Cr2O3 ML were a = b = 6.175 Å. Self-consistent calculations were carried out with an 11 × 11 × 1 k-mesh and a vacuum distance of 15 Å was utilized in the direction normal to the layer. The convergence criterion of energy was set to 0.01 meV for unit cell and the atomic positions were fully relaxed until the force on each atom was smaller than 0.001 eV Å−1.
Phonon and ab initio molecular dynamics
To investigate the dynamical stability, we also calculated the phonon dispersion curve by using PHONOPY code42. Force criterion for the ionic step was set to 10−8 eV Å−1 for the phonon calculations. Force constant matrices used in the phonon calculations were determined by density functional perturbation theory using the VASP code with a supercell method featuring a 3 × 3 × 1 supercell and 3 × 3 × 1 k-points. Ab initio MD calculations were performed to check the thermal stability of 2D Cr2O3 ML. We carried out the MD simulations of Cr2O3 ML at 300 K. To explore this aspect, 3 × 3 supercell containing 45 atoms was used. The time step was set to 0.5 fs and the simulation was run up to 5 ps. A Nosé–Hoover thermostat was used to control the ionic temperature43,44.
Magnetic anisotropy calculations details
MAEs were calculated by including SOC. A very strict criterion of 10−8 eV atom−1 for the total energy convergence was set and the converged MAE results were obtained at high 41 × 41 × 1 k-points. The detailed information on the MAE calculations and the influence of different approximations using VASP can be seen in ref. 45.
Nonequilibrium green’s function method
For the transport calculations, we used the nonequilibrium Green’s function method based on DFT. All the electron transport calculations were carried out using RSPACE code46,47,48,49,50, which is based on the real-space finite-difference method51,52. Exchange-correlation interactions were treated by LDA, and the norm-conserving pseudopotentials53 of Troullier and Martins54 were used for the core electrons with a grid spacing of 0.15 Å. The relative spin directions of two electrodes were changed to obtain zero bias-dependent transmission.
Data availability
The data that supports the findings of this study are available within the article.
Code availability
The calculations were implemented using the VASP, Vampire, Phonopy, and RSPACE packages.
References
Mas-Ballesté, R., Gómez-Navarro, C., Gómez-Herrero, J. & Zamora, F. 2D materials: to graphene and beyond. Nanoscale 3, 20–30 (2011).
Mak, K. F. & Shan, J. Photonics and optoelectronics of 2D semiconductor transition metal dichalcogenides. Nat. Photonics 10, 216–226 (2016).
Liu, Y. et al. Van der Waals heterostructures and devices. Nat. Rev. Mater. 1, 16042 (2016).
Huang, B. et al. Layer-dependent ferromagnetism in a van der Waals crystal down to the monolayer limit. Nature 546, 270–273 (2017).
Gong, C. et al. Discovery of intrinsic ferromagnetism in two-dimensional van der Waals crystals. Nature 546, 265–269 (2017).
Bonilla, M. et al. Strong room-temperature ferromagnetism in VSe2 monolayers on van der Waals substrates. Nat. Nanotechnol. 13, 289 (2018).
Chen, P. et al. Ultrathin nanosheets of feroxyhyte: a new two-dimensional material with robust ferromagnetic behavior. Chem. Sci. 5, 2251–2255 (2014).
Žutić, I., Fabian, J. & Das Sarma, S. Spintronics: fundamentals and applications. Rev. Mod. Phys. 76, 323–410 (2004).
de Groot, R. A., Mueller, F. M., Engen, P. Gvan & Buschow, K. H. J. New class of materials: half-metallic ferromagnets. Phys. Rev. Lett. 50, 2024–2027 (1983).
Zhou, X., Hang, Y., Liu, L., Zhang, Z. & Guo, W. A large family of synthetic two-dimensional metal hydrides. J. Am. Chem. Soc. 141, 7899–7905 (2019).
Hu, Y. et al. High Curie temperature and carrier mobility of novel Fe, Co and Ni carbide MXenes. Nanoscale 12, 11627–11637 (2020).
Zhang, S., Xu, R., Duan, W. & Zou, X. Intrinsic half-metallicity in 2D ternary chalcogenides with high critical temperature and controllable magnetization direction. Adv. Funct. Mater. 29, 1808380 (2019).
Wang, B. et al. MnX (X = P, As) monolayers: a new type of two-dimensional intrinsic room temperature ferromagnetic half-metallic material with large magnetic anisotropy. Nanoscale 11, 4204–4209 (2019).
Choudhuri, I., Bhauriyal, P. & Pathak, B. Recent advances in graphene-like 2D materials for spintronics applications. Chem. Mater. 31, 8260–8285 (2019).
Nagel, M. et al. Ultrathin transition-metal oxide films: thickness dependence of the electronic structure and local geometry in MnO. Phys. Rev. B 75, 195426 (2007).
Zhao, G. et al. Synthesizing MnO2 nanosheets from graphene oxide templates for high performance pseudosupercapacitors. Chem. Sci. 3, 433–437 (2012).
Zavabeti, A. et al. A liquid metal reaction environment for the room-temperature synthesis of atomically thin metal oxides. Science 358, 332–335 (2017).
Ma, R. & Sasaki, T. Nanosheets of oxides and hydroxides: ultimate 2D charge-bearing functional crystallites. Adv. Mater. 22, 5082–5104 (2010).
Guo, Y. et al. Magnetic two-dimensional layered crystals meet with ferromagnetic semiconductors. InfoMat 2, 639–655 (2020).
Zhao, C., Zhang, H., Si, W. & Wu, H. Mass production of two-dimensional oxides by rapid heating of hydrous chlorides. Nat. Commun. 7, 12543 (2016).
Zhao, P., Ma, Y., Wang, H., Huang, B. & Dai, Y. Room-temperature quantum anomalous hall effect in single-layer CrP2S6. J. Phys. Chem. C 123, 14707–14711 (2019).
Wu, Q., Zhang, Y., Zhou, Q., Wang, J. & Zeng, X. C. Transition-metal dihydride monolayers: a new family of two-dimensional ferromagnetic materials with intrinsic room-temperature half-metallicity. J. Phys. Chem. Lett. 9, 4260–4266 (2018).
Wu, Q., Xu, W. W., Lin, D., Wang, J. & Zeng, X. C. Two-dimensional gold sulfide monolayers with direct band gap and ultrahigh electron mobility. J. Phys. Chem. Lett. 10, 3773–3778 (2019).
Chen, Z. et al. Two-dimensional intrinsic ferromagnetic half-metals: monolayers Mn3X4 (X = Te, Se, S). J. Mater. Sci. 55, 7680–7690 (2020).
Lv, H., Wu, D., Li, X., Wu, X. & Yang, J. Two-dimensional transitional metal dihydride crystals with anisotropic and spin-polarized Fermi Dirac cones. J. Mater. Chem. C 6, 11243–11247 (2018).
Zhuang, H. L., Xie, Y., Kent, P. R. C. & Ganesh, P. Computational discovery of ferromagnetic semiconducting single-layer CrSnTe3. Phys. Rev. B 92, 035407 (2015).
Moaied, M., Lee, J. & Hong, J. A 2D ferromagnetic semiconductor in monolayer Cr-trihalide and its Janus structures. Phys. Chem. Chem. Phys. 20, 21755–21763 (2018).
Ertekin, E., Chrzan, D. C. & Daw, M. S. Topological description of the Stone-Wales defect formation energy in carbon nanotubes and graphene. Phys. Rev. B 79, 155421 (2009).
Ceperley, D. M. & Alder, B. J. Ground state of the electron gas by a stochastic method. Phys. Rev. Lett. 45, 566–569 (1980).
Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized gradient approximation made simple. Phys. Rev. Lett. 77, 3865–3868 (1996).
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).
Perdew, J. P., Ruzsinszky, A., Csonka, G. I., Constantin, L. A. & Sun, J. Workhorse semilocal density functional for condensed matter physics and quantum chemistry. Phys. Rev. Lett. 103, 026403 (2009).
Zhang, L. et al. Two-dimensional honeycomb-kagome Ta2S3: a promising single-spin Dirac fermion and quantum anomalous hall insulator with half-metallic edge states. Nanoscale 11, 5666–5673 (2019).
Yin, J.-X. et al. Negative flat band magnetism in a spin–orbit-coupled correlated kagome magnet. Nat. Phys. 15, 443–448 (2019).
Halilov, S. V., Perlov, A. Y. A., Oppeneer, P. M., Yaresko, A. N. & Antonov, V. N. Magnetocrystalline anisotropy energy in cubic Fe, Co, and Ni: applicability of local-spin-density theory reexamined. Phys. Rev. B 57, 9557–9560 (1998).
Evans, R. F. L. et al. Atomistic spin model simulations of magnetic nanomaterials. J. Phys. Condens. Matter 26, 103202 (2014).
Lado, J. L. & Fernández-Rossier, J. On the origin of magnetic anisotropy in two dimensional CrI3. 2D Mater. 4, 035002 (2017).
Fei, Z. et al. Two-dimensional itinerant ferromagnetism in atomically thin Fe3GeTe2. Nat. Mater. 17, 778–782 (2018).
Kresse, G. & Furthmüller, J. Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set. Comput. Mater. Sci. 6, 15–50 (1996).
Kresse, G. & Furthmüller, J. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Phys. Rev. B 54, 11169–11186 (1996).
Blöchl, P. E. Projector augmented-wave method. Phys. Rev. B 50, 17953–17979 (1994).
Togo, A. & Tanaka, I. First principles phonon calculations in materials science. Scr. Mater. 108, 1–5 (2015).
Nosé, S. A unified formulation of the constant temperature molecular dynamics methods. J. Chem. Phys. 81, 511–519 (1984).
Hoover, W. G. Canonical dynamics: equilibrium phase-space distributions. Phys. Rev. A 31, 1695–1697 (1985).
Błoński, P. & Hafner, J. Density-functional theory of the magnetic anisotropy of nanostructures: an assessment of different approximations. J. Phys. Condens. Matter 21, 426001 (2009).
Ono, T. & Hirose, K. Timesaving double-grid method for real-space electronic-structure calculations. Phys. Rev. Lett. 82, 5016–5019 (1999).
Ono, T. & Hirose, K. Real-space electronic-structure calculations with a time-saving double-grid technique. Phys. Rev. B 72, 085115 (2005).
Hirose, K., Ono, T. & Fujimoto, Y. First-Principles Calculations in Real-Space Formalism: Electronic Configurations and Transport Properties of Nanostructures (Imperial College Pr, 2005).
Ono, T. et al. Real-space electronic structure calculations with full-potential all-electron precision for transition metals. Phys. Rev. B 82, 205115 (2010).
Ono, T. & Tsukamoto, S. Real-space method for first-principles electron transport calculations: self-energy terms of electrodes for large systems. Phys. Rev. B 93, 045421 (2016).
Chelikowsky, J. R., Troullier, N. & Saad, Y. Finite-difference-pseudopotential method: electronic structure calculations without a basis. Phys. Rev. Lett. 72, 1240–1243 (1994).
Chelikowsky, J. R., Troullier, N., Wu, K. & Saad, Y. Higher-order finite-difference pseudopotential method: an application to diatomic molecules. Phys. Rev. B 50, 11355–11364 (1994).
Kobayashi, K. Norm-conserving pseudopotential database (NCPS97). Comput. Mater. Sci. 14, 72–76 (1999).
Troullier, N. & Martins, J. L. Efficient pseudopotentials for plane-wave calculations. Phys. Rev. B 43, 1993–2006 (1991).
Acknowledgements
This research was partially supported by MEXT as a social and scientific priority issue (Creation of new functional devices and high-performance materials to support next-generation industries) to be tackled by using post-K computer, JSPS KAKENHI Grant No. 19K15381, and JSPS Core-to-Core program (Controlled Interfacing of 2D materials for Integrated Device Technology). The numerical calculations were carried out using the computer facilities of the Institute for Solid State Physics at the University of Tokyo, the Center for Computational Sciences at University of Tsukuba, and the K computer provided by the RIKEN Advanced Institute for Computational Science through the HPCI System Research project (Project ID: hp190172).
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A.H. conceived the idea and performed DFT calculations. K.N. carried out the nonequilibrium Green’s function calculations. M.U.F. described the magnetic interactions of the magnetic layer. T.O. supervised the work, verified overall results, and commented on the manuscript. All the authors contributed to writing the manuscript.
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Hashmi, A., Nakanishi, K., Farooq, M.U. et al. Ising ferromagnetism and robust half-metallicity in two-dimensional honeycomb-kagome Cr2O3 layer. npj 2D Mater Appl 4, 39 (2020). https://doi.org/10.1038/s41699-020-00174-0
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DOI: https://doi.org/10.1038/s41699-020-00174-0
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