Abstract
As the inversion symmetry is broken at a surface, spin-orbit interaction gives rise to spin-dependent energy shifts – a phenomenon which is known as the spin Rashba effect. Recently, it has been recognized that an orbital counterpart of the spin Rashba effect – the orbital Rashba effect – can be realized at surfaces even without spin-orbit coupling. Here, we propose a mechanism for the orbital Rashba effect based on sp orbital hybridization, which ultimately leads to the electric polarization of surface states. For the experimentally well-studied system of a BiAg2 monolayer, as a proof of principle, we show from first principles that this effect leads to chiral orbital textures in k-space. In predicting the magnitude of the orbital moment arising from the orbital Rashba effect, we demonstrate the crucial role played by the Berry phase theory for the magnitude and variation of the orbital textures. As a result, we predict a pronounced manifestation of various orbital effects at surfaces, and proclaim the orbital Rashba effect to be a key platform for surface orbitronics.
The spin Rashba effect as a fundamental manifestation of spin-orbit coupling (SOC) at surfaces has revolutionized the spintronics research, and served as a foundation for a new field of spintronics rooted in relativistic effects – spin-orbitronics1,2,3,4. As a consequence of the spin Rashba effect, the surface states created as a result of SOC and surface potential gradient exhibit finite spin polarization, which forms chiral textures in reciprocal k-space. This gives rise to a multitude of prominent phenomena such as Dzyaloshinskii-Moriya interaction5,6,7,8,9, spin Hall effect10, direct and inverse Edelstein effects11,12, quantum anomalous Hall effect13, and current-induced spin-orbit torques14,15,16.
Only recently it has been realized that many of the spin-orbitronic effects can be rethought in terms of their “parent” orbital analogs brought to the “spin” level by SOC17,18,19,20,21,22,23,24,25. This leads to the notion of orbitronics as a promising branch of electronics which operates with the orbital degree of electrons rather than their spin. The orbital moment (OM) of electrons in a solid, being an evasive quantity until very recently26,27, offers higher flexibility with respect to its magnitude and internal structure as compared to spin, and it is a key quantity for novel and promising effects in orbitronics such as the gyrotropic magnetic effect28 and orbital Edelstein effect29. The orbitronic analogue of the spin Rashba effect is the orbital Rashba effect (ORE), which results in the emergence of chiral OM textures of the states in k-space even without SOC, and manifests in the “conventional” Rashba effect in the spin channel upon including SOC into the picture17,18,19,20,21,22,23. Indeed, circular dichroism measurements of Au(111) and Bi2Se3 surfaces are consistent with the prediction of the ORE forming non-trivial chiral OM textures in k-space22,23. On the other hand, quasi-particle interference experiments performed on another Rashba systems, the surface of Pb/Ag(111)30 and Bi/Ag(111)31, demonstrate clear fingerprints of spin-orbital-flip scattering, which implies the vital role of the orbital degree of freedom of electrons for surface scattering. As the spin Rashba effect played a key role in the development of spintronics, our understanding of the ORE and the ability to control its properties is pivotal for bringing orbitronics to the surface realm.
In this work, we introduce a mechanism for the ORE at surfaces, which originates in the orbital sp hybridization and gives rise to pronounced ORE even without SOC in sp surface alloys such as BiAg2 monolayer. We elucidate that the sp hybridization gives rise to the orbital magnetoelectric coupling and intrinsically links the ORE with electric polarization of states at the surface. Moreover, by referring to explicit first principles calculations, we demonstrate that including non-local effects32,33,34,35,36,37,38 can drastically enhance the magnitude of the ORE-driven orbital polarization of the surface states as compared to the k-dependent OM obtained from simple atomic arguments. We speculate that such an enhancement, which is particularly prominent in the vicinity of band crossings in the surface electronic structure, can result in a giant magnitude of various orbitronics phenomena such as orbital Hall effect24,25, gyrotropic magnetic effect28, and current-induced orbital magnetization29. This marks the ORE as the most promising platform for realizing orbitronics at surfaces.
Results
Tight-binding model
We start the discussion of the ORE with tight-binding considerations. While previously only pure p- and d-orbital systems have been studied18,19,39, here we study monolayer of sp-derived surface alloys such as BiAg230,40,41, which is different in that sp hybridization is important. The tight-binding Hamiltonian can be generally written as:
where Hp(s)(k) is a Hamiltonian in the subspace spanned by p(s) orbitals, and h(k) describes the effect of sp hybridization. For a two-dimensional square lattice in the xy-plane with three p orbitals and one s orbital at each site, we choose the basis states as . Here, ϕnR denotes the n-th (n = px, py, pz, s) atomic orbital centered at the Bravais lattice R, and N is the number of lattice sites. In this basis, the hybridization assumes the form:
where γsp is the nearest-neighbor hopping amplitude between px(y) and s orbitals, a is the lattice constant, describes the effect of spz hybridization by a surface potential gradient εz, and e > 0 is the elementary positive charge. The effect of SOC is included into the Hamiltonian as , where λsoc is the spin-orbit strength, is the operator of spin, and
is the representation of the atomic contribution of the orbital angular momentum operator42. Here, r and p denote the canonical position and momentum operators, respectively. Although the general conclusions that we draw from the tight-binding model do not depend on the exact choice of the hopping parameters, they can be easily tuned such that the tight-binding band structure closely resembles the first principles one of the BiAg2 monolayer (Fig. 1).
Orbital Rashba effect
Neglecting for the moment the effect of SOC and assuming |Hp(k) − Hs(k)| ≫ |h(k)| as is the case for BiAg2 in the long-wavelength limit of k → 0, we can perturbatively downfold the h(k) term to arrive at an effective Hamiltonian (see Supplementary Information):
where Hp,eff(k) = Hp(k) + HOR(k). The expression
is known as the orbital Rashba Hamiltonian since it resembles the conventional spin Rashba Hamiltonian with the orbital angular momentum operator replacing that of spin. Remarkably, the combined effect of sp hybridization and surface potential gradient is concisely described by the orbital Rashba Hamiltonian within the subspace spanned by p orbitals. Thus, the orbital Rashba physics arises not from the electron’s spin but from the orbital degrees of freedom even without SOC. In analogy to the Rashba constant of the conventional spin Rashba model, the parameter
is called the orbital Rashba constant, with ΔEsp(k) denoting the energy gap between s- and p-derived bands, and η ~ 1 being a parameter dependent on the lattice structure. Using the specific tight-binding model parameters for BiAg2 (see Supplementary Information), we estimate the orbital Rashba constant to be about 1 eV ⋅ Å. From Eq. (6) it is clear that the ORE roots in the sp orbital hybridization, and that the strength of the orbital Rashba effect is directly proportional to the value of the surface potential gradient associated with the buckling of Bi atoms in BiAg2. This implies that the desired properties of the ORE can be designed by controlling the band hybridization via chemical and structural engineering.
Crystal field splitting
In contrast to the conventional Rashba effect, the ORE is very sensitive to the crystal field splitting (CFS), which quenches the OM. In the absence of the CFS, that is, when with as corresponding energy eigenvalues of px(y)- and pz-derived states at k = 0, the expectation value of the OM is given by
within the so-called atom-centered approximation for the OM, which takes into account only intra-atomic contributions. Here, and are unit vectors along the z-axis and vector k, respectively, is the pl-derived eigenstate of Hp,eff(k), and l = {−1, 0, +1} is the angular momentum quantum number with respect to the quantization axis . In the vicinity of the Fermi energy, the p-derived bands can thus be denoted in terms of their dominant orbital character as p−1, p0, and p+1 in the order of increasing energy (Fig. 1c,d). The corresponding k-dependent eigenenergies are E−1(k), E0(k), and E+1(k). The associated k-linear orbital-dependent energy splitting arising due to the orbital Rashba term in Hp,eff(k) amounts to ΔEOR = lαOR|k| in the long-wavelength limit. However, in the presence of the CFS, although its direction remains intact, the expectation value of the OM is reduced by a factor of 2αOR|k|/ΔCFS, when assuming |ΔCFS| ≫ |αORk|. For this reason, the orbital-dependent energy splitting appears from the second order in k if ΔCFS ≠ 0, which can be seen from Eq. (5).
Relation to electric polarization
Consider an orbital-coherent state , that is, an eigenstate of Hhop(k) with ΔCFS = 0 which exhibits a quantized value of OM (e.g., due to an applied in-plane magnetic field or the ORE):
where l = {−1, 0, +1} is the orbital angular momentum quantum number with respect to the direction of some in-plane unit vector . While in previous studies the electric polarization within the ORE was introduced phenomenologically17,20, one can show from perturbation theory arguments that such an orbital-coherent state naturally exhibits an electric polarization perpendicular to the surface plane:
where the parameter
is what we call the orbital Rashba susceptibility. The structure of χOR reflects that the electric polarization arises from the sp hybridization (Fig. 2a). From Eq. (6) it is clear that , and that the orbital Rashba Hamiltonian as given by Eq. (5) can be understood as a dipole coupling between an electric field at the surface with the operator of electric polarization, , where (Fig. 2b). Physically, it means that within the ORE the non-trivial orbital texture of states in k-space arises so as to gain maximal energy by the interaction of the states’ polarization with the surface electric field. Thus, the ORE can be seen as a consequence of orbital magnetoelectric coupling at surfaces.
Atom-centered approximation from first principles
In order to verify our predictions in a realistic system, we evaluate the k- and band-resolved value of the OM in BiAg2 from first principles, which is given by in ACA. Here, ψnk is an eigenstate, rμ is the position operator relative to atom μ, the summation is performed over all atoms in the lattice, and the real-space integration is restricted locally to atom-centered muffin-tin spheres. Computed in such a way OM is a direct generalization to the first principles framework of the OM computed in ACA from tight-binding. In Fig. 3a–c, we show the distribution of the OM in k-space for the p-derived bands p−1, p0, and p+1 in absence of SOC, and observe clockwise (−1), zero, and counter-clockwise (+1) type of chiral behavior of this distribution around the Γ-point, respectively. The magnitude of the OM without SOC along different high-symmetry lines is shown in Fig. 3d. While the OM reaches as much as 0.27μB for the p+1 band in the middle of the Brillouin zone, we can use its behaviour with k in the vicinity of the Γ-point to estimate the magnitude of the orbital Rashba constant αOR. First, we note that a small but finite value of the slope in the OM of p0 as well as visible differences in the behavior of the OM of p−1 and p+1 bands can be observed, in contrast to our prediction Eq. (8). The reason for the discrepancy lies in a non-zero crystal field splitting, which we can estimate from Fig. 1d to be ΔCFS ≈ 0.76 eV. Taking this into account, the orbital Rashba constant of p−1 and p+1 bands amounts to 0.96 eV ⋅ Å and 1.38 eV ⋅ Å, respectively. Similarly, we also find orbital chiralities near the K-point. Investigating further the influence of SOC, we found no qualitative changes in the distribution of the OM in the Brillouin zone. However, we clearly see that the resulting “Rashba” spin texture in reciprocal space, emerging upon including SOC, is strictly bound to the local direction of the OM. Details on these results are provided in the Supplementary Information. Finally, we display in Fig. 4f and g the chirality of the OM at the Fermi surface both with and without SOC taken into consideration, respectively.
Berry phase theory in films
The primary manifestation of the ORE in solids is the k- and band-dependent generation of finite OM. For understanding this fundamental effect and predicting its magnitude, it is crucial to evaluate the magnitude of the OM properly without assuming any approximations such as the ACA. Recently, it was shown that a rigorous treatment of OM in solids within the complete Berry phase description32,33,34,35 naturally accounts for non-local effects37. Thereby, theoretical estimations of OM in magnetic materials of various nature have significantly improved26,27,38.
Since the ORE manifests in the generation of in-plane OM, following the procedure of ref. 35, we extended the previous formulation to the case of in-plane components of OM of a film finite along the z-axis. The expression for the in-plane components of the OM in the modern theory is given by
where unk is an eigenstate of the lattice-periodic Hamiltonian H(k) with the eigenvalue En(k), and EF is the Fermi energy. Equation (11) can be further decomposed into the so-called local circulation term and the itinerant circulation term The latter expression is connected to the projected Berry curvature
which is closely related to the well-known Berry curvature in bulk systems by formally replacing z with .
Inserting the model orbital Rashba Hamiltonian, Eq. (5), directly into Eq. (11), we find that
in the long-wavelength limit, where l is the angular-momentum quantum number defined in Eq. (7). Assuming the typical values , we find not only that ACA and modern OM exhibit the same chirality of the distribution, but also that in the vicinity of the Γ-point within the model analysis.
Berry phase theory from first principles
To investigate whether significant differences between the ACA and modern treatment of OM arise in a realistic situation, we evaluate from first principles . In Fig. 4, we show the OM distribution evaluated from the modern theory (Fig. 4a,c) and ACA (Fig. 4b,d), where the individual contributions of all occupied bands were summed up for each k point. In this figure, the distribution of the OM within the modern approach and ACA is similar around the Γ-point both in magnitude and overall distribution, in accordance with our model considerations. Near the K-point, however, the distribution of the modern OM without SOC deviates significantly from the ACA result. If SOC is taken into account, the difference between the two approaches is even more drastic as it amounts to one order of magnitude. In Fig. 4, the visible discontinuity of the OM distribution occurs along the Fermi surface lines (Fig. 4e–h). Directly at the Fermi surface, the itinerant contribution to the OM in the modern theory vanishes and we may restrict ourselves to visualizing in Fig. 4e and g the local circulation from the modern theory, without and with SOC, respectively. In contrast, within ACA there is no such decomposition of the Fermi-surface contribution (Fig. 4f,h). The OM of Fermi-surface states plays a crucial role in various orbital magnetoelectric phenomena28,29.
Within the Berry phase theory, one of the most remarkable features of the OM in bulk is its correlation with the Berry curvature in k-space, which often exhibits a spiky behavior in the vicinity of band crossings36. In our formalism for the in-plane OM in thin films as expressed by Eq. (11), the projected Berry curvature, Eq. (12), is a key ingredient. It behaves similarly to the conventional Berry curvature in that it can exhibit singular behavior at band crossings as a consequence of the rapid variation of the wave functions with k. Following this spirit, we also seek for such a spiky behavior in the local circulation mLC(k) by studying the OM in the vicinity of the band crossing in the electronic structure of BiAg2 which is close to the M-point and about 0.2 eV below the Fermi level. Setting EF in Eq. (11) to the energy of the crossing and treating all bands below this energy as occupied, we observe a singular behavior of the OM magnitude within the modern theory in the vicinity of the crossing point (Fig. 5a). This behavior can be directly correlated with sizable OM contributions of those states which constitute the band crossing. At the point of singularity, the modern-theory OM is purely due to the local circulation and it reaches as much as 1.01 μB in magnitude, while the ACA predicts a tiny value of 0.03 μB. Remarkably, both ACA and modern theory agree qualitatively in their prediction of the behavior of the OM away from the band crossing (see Supplementary Information).
Two-band model near the band crossing
To study the aforementioned behavior of the OM near the band crossing from the model point-of-view, we consider the following two-band Hamiltonian:
where σ is the vector of Pauli matrices reflecting the orbital degree of freedom of two chosen basis states: |φs,k〉, and . We assume that dx(k) = 0, dy(k) = γspkxa + Vz, and dz(k) = δ, where a is the lattice constant, δ is the energy gap of the massive Dirac-like dispersion along kx, γsp is the nearest-neighbor hopping amplitude between s and px orbitals, and expresses the breaking of inversion symmetry. The band structure of this Hamiltonian is shown in Fig. 5b, where we assumed a = 5 Å, Vz = 0.1 eV, γsp = 1 eV, and δ = 5 meV. We represent the position operator z in the specified basis as
where px = pz = 0 and . Taking into account the representation (15) and applying Eq. (11), we obtain an expression for the in-plane OM from the modern theory for the general two-band Hamiltonian (14):
where is the direction of d(k) and the “+” (“−”) sign stands for upper (lower) band. In the second line, owing to the fact that in our model , we related the modern OM to the derivative of , that is, the z-component of the electric polarization of the upper (lower) band as defined in Eq. (9).From this generic expression we clearly observe that the origin of the non-vanishing OM within the modern theory lies in the gradient of the electric polarization in reciprocal space. Using the parameters stated above and setting EF = 3 meV and py = 2 Å, we compute the OM of all occupied states in the vicinity of the band crossing from both modern theory, Eq. (16), and ACA, Eq. (3). By replacing further EF with |d(k)| in Eq. (16), we obtain the Fermi-surface contribution due to the self-rotation of the wave packet32, which determines the orbital magnetoelectric response28,29. Based on the results shown in Fig. 5b, we conclude that while the values of are strictly bound by μB everywhere as can be confirmed analytically, the pronounced singular behavior of with large values within the gap can be attributed solely to the rapid variation of the electric polarization in the vicinity of the crossing.
Discussion
We have shown that sp orbital hybridization is the main mechanism for the ORE at surfaces of sp-alloys, which is manifest already without SOC. Just like the spin Rashba effect follows from the ORE via SOC, we can expect other orbital-dependent phenomena to be formulated and discovered, from which SOC recovers their spin analogues. One remarkable example is orbital analogue of the quantum anomalous Hall effect, where the quantized edge state is orbital-polarized43. Another example is the recent formulation of the orbital version of the Dzyaloshinskii-Moriya interaction governing the formation of chiral structures such as domain walls and skyrmions44.
Our simulations reveal the complexity of the orbital textures driven by ORE, and their sensitivity to the electronic structure of realistic materials. This means that the desired properties of the ORE, and phenomena it gives rise to, can be designed by proper electronic-structure engineering. Moreover, by making use of both spin and orbital degrees of freedom, one can generate and manipulate arising spin and orbital textures in k-space. While for the case of BiAg2 considered here the spin aligns collinearly to the OM in the presence of SOC, a Rashba effect with respect to the total angular momentum emerges in each of the j = 3/2 and j = 1/2 branches in the regime where SOC is dominant over the ORE17,20. Based on a similar idea, an orbital version of the Chern insulator state in a situation of very large SOC has been recently proposed45.
We predict that within the ORE, in contrast to the spin Rashba effect, the magnitude of the OM in the vicinity of band crossings can reach gigantic values. This observation has very far-reaching consequences for the magnitude of effects which are directly associated with the OM at the Fermi surface. This particularly concerns the orbital magnetoelectric effect, as recently discussed in the context of orbital Edelstein effect29 and gyrotropic magnetic effect28. Within the orbital Edelstein effect, a finite OM at the Fermi surface is generated by an asymmetric change in the distribution function created by an electric field. In the gyrotropic magnetic effect, discussed intensively these days with respect to topological metals46,47, an external magnetic field gives rise to an electrical current28. Both phenomena rely crucially on the magnitude of the local orbital moments at the Fermi surface of materials, and we predict here that they can be drastically enhanced by tuning the electronic structure such that the singularities in the OM, which we disclose in our work, are positioned at the Fermi level. The generally enhanced predicted magnitude of the Berry-phase OM of the occupied states, as compared to the OM computed from the commonly used approximation, can also manifest in the re-evaluation of the magnitude of other effects such as the orbital Hall effect24,25.
Let us comment on the effect of disorder on the OM texture. Unlike the spin, the OM is susceptible to the CFS as discussed above, thus it is natural to expect that the OM will be less robust to non-magnetic disorder as compared to the spin moment. Nevertheless, distinct orbital characters of surface states have been measured in recent experiments with angle-resolved photoemission spectroscopy by controlling the polarization of the incident light21,23,48,49,50, which implies that the orbital texture of these surface states survives even with a moderate amount of disorder. In addition, according to the modern theory32,33,34,35, the OM is intimately related to the momentum-space Berry curvature, which is known to be particularly robust with respect to disorder51,52. Moreover, Zhu et al. have shown recently that the disorder changes the OM merely by renormalizing the quasiparticle energy spectrum53. We would like to emphasize, however, that the promotion of certain parts of the Fermi surface by disorder scattering is essential in generating large current-induced OM, rendering the utilization of disorder details crucial to bring orbitronics to the surface realm.
An additional flavor to the ORE is the intrinsic valley degree of freedom inherent to systems of the type studied here: because of time-reversal symmetry the points of singularity in the OM always come in pairs. Since the OM is opposite for opposite valleys, the overall OM integrated over the Brillouin zone is zero in the ground state, and orbital magnetoelectric response becomes strongly valley-dependent. Exploiting the ORE for the purpose of generating sizable ground state net OM at surfaces has to be done in combination with generating a non-vanishing exchange field and magnetization in the system. This can give rise to a plethora of effects relying on intertwined spin and orbital degrees of freedom in complex magnetic materials.
Methods
First principles calculation
We performed self-consistent density-functional theory calculations of the electronic structure of BiAg2 using the film mode of the fleur code54, which implements the FLAPW method55,56. Exchange and correlation effects were treated within the generalized gradient approximation57. We assumed a R30° unit cell (see Fig. 2a) with the in-plane lattice constant a = 9.47a0, where a0 is Bohr’s radius. The surface relaxation of Bi was set to d = 1.61a0, and the muffin-tin radii of Bi and Ag were chosen as 2.80a0 and 2.59a0, respectively. We used as plane-wave cutoff and sampled the irreducible Brillouin zone using 110 points. Spin-orbit coupling was included self-consistently within the second-variation scheme58.
Based on the converged charge density, maximally-localized Wannier functions (MLWFs) were obtained in a post-processing step employing an equidistant 16 × 16 k-mesh. Starting from sp2 and pz trial orbitals on Bi as well as s, p, and d trial functions on Ag, we constructed 44 MLWFs out of 120 energy bands using the wannier90 program59. The frozen window was set 2.78 eV above the Fermi energy. Subsequently, we calculated the OM in (i) the ACA, and (ii) the Berry phase theory according to the scheme proposed by Lopez et al.27.
Additional Information
How to cite this article: Go, D. et al. Toward surface orbitronics: giant orbital magnetism from the orbital Rashba effect at the surface of sp-metals. Sci. Rep. 7, 46742; doi: 10.1038/srep46742 (2017).
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Material
Acknowledgments
D.G. acknowledges the financial support from the Global Ph.D. Fellowship Program funded by NRF (2014H1A2A1019219). H.W.L. is supported by the National Research Foundation of Korea (NRF) grant (No. 2011-0030046). We thank Changyoung Kim, Juba Bouaziz, Manuel dos Santos Dias, Philipp Rüßmann, and Samir Lounis for stimulating discussions.
Footnotes
The authors declare no competing financial interests.
Author Contributions D.G. uncovered the mechanism of the orbital Rashba effect by tight-binding model consideration. D.G., J.-P.H., and P.M.B. performed first principles calculations. D.G., J.-P.H., and Y.M. wrote the manuscript. D.G., J.-P.H., P.M.B., F.F., G.B., H.-W.L., Y.M., and S.B. discussed the data and contributed to the paper.
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