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. 2024 Nov 7;14:27041. doi: 10.1038/s41598-024-77403-9

Spin-Hall conductivity and optical characteristics of noncentrosymmetric quantum spin Hall insulators: the case of PbBiI

Mohammad Mortezaei Nobahari 1,, Carmine Autieri 2
PMCID: PMC11544231  PMID: 39511322

Abstract

Quantum spin Hall insulators have attracted significant attention in recent years. Understanding the optical properties and spin Hall effect in these materials is crucial for technological advancements. In this study, we present theoretical analyses to explore the optical properties, Berry curvature and spin Hall conductivity of pristine and perturbed PbBiI using the linear combination of atomic orbitals and the Kubo formula. The system is not centrosymmetric and it is hosting at the same time Rashba spin-splitting and quantized spin Hall conductivity. Our calculations reveal that the electronic structure can be modified using staggered exchange fields and electric fields, leading to changes in the optical properties. Additionally, the spin Berry curvature and spin Hall conductivity are investigated as a function of the energy and temperature. The results indicate that due to the small dynamical spin Hall conductivity, generating an ac spin current in the PbBiI requires the use of external magnetic fields or magnetic materials.

Subject terms: Nanoscience and technology, Condensed-matter physics

Introduction

In the realm of condensed matter physics, the emergence of topological materials has ushered in a new era of exploration, leading to the discovery of quantum phenomena with transformative implications. Among these materials, quantum spin Hall (QSH) insulators occupy a pivotal position, representing a paradigm shift in the understanding of topologically nontrivial electronic states1. The notion of a QSH insulator was first proposed by Bernevig Inline graphicInline graphic2, reflecting a revolutionary break from conventional electronic behavior by introducing the concept of topological protection for electronic states. These materials manifest insulating behavior in bulk but host robust conducting edge states topologically protected against back-scattering by time-reversal symmetry, ushering in the promise of dissipationless electronic transport and novel spin-based functionalities35.

Experimental investigations have validated the existence of QSH behavior in various material platforms, ranging from one- and two-dimensional systems to designed heterostructures, expanding the horizons of potential applications of these topological electronic states69. These experimental efforts have illuminated the intricate interplay between topological and electronic properties at the heart of QSH insulators. Recent advances in experimental techniques, ranging from magneto-transport measurements to angle-resolved photoemission spectroscopy, have uncovered a plethora of materials showcasing QSH behavior, expanding the horizon of potential platforms for exploiting the remarkable attributes of these topological materials10,11. Such strides in materials discovery and characterization open avenues for investigating the interplay between topological electronic states and intricate quantum phenomena.

Understanding the implications of QSH insulators extends beyond fundamental physics, venturing into the realm of practical applications in electronics and spintronics. The chiral nature of the edge states in QSH insulators offers the tantalizing prospect of dissipationless spin transport, holding promise for the development of efficient spin logic and memory devices that harness the spin degrees of freedom of electrons1215. Moreover, the intricate interplay between the topological and electronic properties of these materials underpins their potential for realizing topologically protected quantum computation and information processing16,17. Recent theoretical advances have further underscored the potential of QSH insulators in redefining the limits of electronic and spin-based functionalities. The proposals for utilizing edge states in QSH insulators have opened up new avenues for achieving dissipationless spin transport and laying the groundwork for advancements in spin-based information processing and quantum computing18,19. The foundations set forth by the theoretical models have not only provided a roadmap for understanding the fundamental behavior of QSH insulators but also set the stage for exploring their transformative implications20,21. Amid these developments, the experimental realization of the quantum spin Hall effect and the identification of materials exhibiting topologically nontrivial electronic states have paved the way for exploring unique opportunities for harnessing their extraordinary properties22,23. The ensuing synthesis of theory and experiment has propelled the field of topological electronics into a realm of unprecedented promise and potential.

The QSH insulating phase has been investigated in both centrosymmetric2426and noncentrosymmetric systems27,28, however, there are not so many cases where the QSH coexists with the Rashba spin splitting. In this paper, we will study a system where we have both the QSH effect and Rashba spin-splitting. Large Rashba spin-splitting is found in materials formed by heavy elements with strong intrinsic SOC such as Bi, Pb, and W, among others2932. To date, several types of QSHIs have been reported, and recently it proposed a honeycomb noncentrosymmetric QSHIs consisting of IV, V, and VII elements and Rashba-like SOC and unconventional spin texture33. Until now, the properties of this material have been well studied in the presence of various disturbances. It has been shown that the thermodynamic properties of this material can be adjusted by a staggered exchange field34. Additionally, the effect of external fields on the electronic and optical properties of this material has also been well studied3537.

When there is no topological insulator phase, we cannot have the QSH phase but we can still have the ordinary spin Hall effect. The spin Hall conductivity (SHC) is a fundamental property of materials that describes the ability of a material to generate a spin current in response to an applied electric field3843. This phenomenon arises from spin-orbit coupling, where the motion of electrons interacts with their spin degrees of freedom. In the presence of an electric field, electrons experience a transverse deflection due to the spin-orbit interaction, leading to the generation of a spin current perpendicular to the charge current. The SHC tensor quantifies this effect and provides valuable information about the spin dynamics in materials. Understanding and controlling the SHC is crucial for developing spintronic devices, such as spin-based transistors and memory storage devices, which rely on the manipulation of electron spins for information processing4446.

This paper begins by exploring the theoretical background in Theory section to gain insight into the properties of the PbBiI. Next, theoretical frameworks are applied to calculate these properties in Results and discussion section, and the results are summarized in Conclusions section.

Theory

Pristine and perturbed Hamiltonian

The geometric structure of the PbBiI is depicted in Fig. 1(a) with top and side views, consisting of Bi (V), Pb (IV), and I (VII) elements. The distance parameters are approximately Inline graphic 1.3 Å and Inline graphic = 3.04 Å. Previous analysis reveals that the highest valence comes from the Inline graphic-Bi orbitals, while the Inline graphic-Bi orbitals give the most relevant contribution to the lowest conduction band. As a result, we can ignore the Pb and I components in the electronic band structure of PbBiI. Hence, we focus on the single-particle bands with Inline graphic (p-orbitals), Inline graphic for spin angular momentum, and Inline graphic. The bands with jInline graphic=Inline graphic3/2 are far from the Fermi level, and we have left the bands for two spin directions with Inline graphic. Therefore, the effective Hamiltonian in the basis of Inline graphic=Inline graphic,Inline graphic1/2Inline graphic can be expressed as:

graphic file with name M22.gif 1

Fig. 1.

Fig. 1

(a) Side and top view of the geometry structure of the PbBiI with Bi = V, Pb = IV, and I = VII by the buckled parameter Inline graphic and Pb-I Inline graphic and Bi-Pb bond lengths 1.35 and 3.04 Å, respectively. (b) 3D band structure and contour plot of Inline graphic in the Inline graphic-Inline graphic plane.

The onsite energies are determined to be Inline graphic eV and Inline graphic eV while other parameters are obtained from Inline graphicInline graphiccalculations33 and are Inline graphic eV/ÅInline graphic, Inline graphic eV/ÅInline graphic, Inline graphic eV/Å, Inline graphic eV/Å, where Inline graphic, and Inline graphic. The parameter Inline graphic represents the Rashba splitting in the conduction band, while Inline graphic is the spin-orbit coupling between the valence and conduction band. The PbBiI has a bulk gap of Inline graphic eV and the Rashba-like spin splitting gap Inline graphiceV in the valence bands. The spin texture around the valence bands confirms the Rashba-type spin-splitting33.

To introduce perturbations on the PbBiI system, external electric and magnetic exchange fields are applied to the Hamiltonian. The magnetic proximity effect arises from the induction of magnetic exchange fields in a material when it is in proximity to a ferromagnetic or antiferromagnetic substrate. These induced fields influence the orbital angular momentum within the basis, resulting in modifications to the Hamiltonian. Additionally, an external electric field can be applied by placing the PbBiI between two voltage gates. The modified Hamiltonian with perturbation terms Inline graphic is expressed as:

graphic file with name M40.gif 2

where Inline graphic and Inline graphic are the external staggered exchange field and electric field contributions respectively and are given by

graphic file with name M43.gif 3

and

graphic file with name M44.gif 4

The induced exchange field Inline graphic corresponds to the total angular momentum Inline graphic (Inline graphic47, Here, Inline graphic represents the Inline graphic-component of the 2 Inline graphic 2 Pauli matrix, and Inline graphic can be controlled via electric field.

The band structure from the Inline graphic effective Hamiltonian for pristine PbBiI accurately reproduces the first-principles DFT calculations33,37 reported in previous works confirming the reliability of Hamiltonian Eq. (1) and its parameters used in this paper. Figure 1 (b) and Fig. 2 (a) represent 3D and 2D band structure of the unperturbed PbBiI system, obtained from Eq. (1). This band structure comprises two valence and two conduction bands, where the valence band at the Inline graphic point is characterized by the states Inline graphic, and the effective state for the conduction band is Inline graphic. Consequently, the states include Inline graphic, Inline graphic, Inline graphic, Inline graphic. Total density of states of the PbBiI confirms Band structure results as depicted in Fig. 2 (b). The effect of the exchange fields on the band gap is shown if Fig. 2 (c). Applying the exchange field reduces the topological gap and finally for Inline graphic eV (which is equal to the Inline graphic) the topological gap is completely closed and a trivial gap reopens for higher values. This is the typical signature of the band gap in QSH insulators.

Fig. 2.

Fig. 2

(a) Band structure of the pristine PbBiI along the Inline graphic direction and Inline graphic, and (b) the total density of states. (c) Band gap (Inline graphic) as a function of different amounts of exchange fields.

Density of states

By utilizing the Green’s function approach, the density of states (DOS) for the PbBiI can be computed. The DOS can be determined by adding up over the first Brillouin zone,

graphic file with name M65.gif 5

where Inline graphic indicates the number of atoms in each unit cell. The non-interacting Green’s function matrix is acquired through Inline graphic, where Inline graphic represents the broadening factor

graphic file with name M69.gif 6

Using Eqs. (5) and (6), the total DOS reads

graphic file with name M70.gif 7

Optical properties

The optical conductivity tensor, Inline graphic, can be determined using Ohm’s law, which states that Inline graphic, where Inline graphic is the current density, Inline graphic is the electric field, and Inline graphic is the optical conductivity tensor.

graphic file with name M76.gif 8

To calculate Inline graphic, direction-dependent velocities are required. The current operator definition along the Inline graphic direction is Inline graphic

graphic file with name M80.gif 9

Also, the general form of the current operator is

graphic file with name M81.gif 10

that Inline graphic and Inline graphic are intraband and inter-band direction-depended velocities along the Inline graphic-direction.

By using linear response theory, the optical conductivity is given as

graphic file with name M85.gif 11

where Inline graphic is the spin degeneracy, Inline graphic is photon frequency and Inline graphic is the 2D planar area.

Using Eq. (11), the interband optical conductivity is given as4850:

graphic file with name M89.gif 12

where Inline graphic is the Fermi-Dirac distribution at a constant temperature Inline graphic and chemical potential Inline graphic, Inline graphic represents the eigenvalue of the energy, Inline graphicdenotes the finite damping between the conduction and valence bands, and Inline graphic and Inline graphic are velocities along the Inline graphic and Inline graphic-directions respectively.

Another important optical property is the electron energy loss spectroscopy (EELS). The energy electron loss spectrum is a type of spectroscopy technique used to study the electronic properties of materials. It involves measuring the energy lost by electrons as they interact with a sample, which can provide information about the electronic structure and bonding of the material. The spectrum is generated by bombarding the sample with high-energy electrons and then measuring the energy distribution of the scattered electrons. The resulting spectrum can reveal details about the valence and conduction bands of the material, as well as the presence of impurities or defects. To calculate EELS, we need the dielectric function which is given by:

graphic file with name M99.gif 13

where Inline graphic is the relative permittivity and Inline graphic is the PbBiI thickness. One can calculate the EELS as

graphic file with name M102.gif 14

We can determine the reflectivity by using the refractive index Inline graphic and extinction coefficient Inline graphic and dielectric function. We have

graphic file with name M105.gif 15

and

graphic file with name M106.gif 16

that we have write Inline graphic. Reflectivity can be calculated as

graphic file with name M108.gif 17

Spin Hall conductivity

We calculate both static (Inline graphic) and dynamic (Inline graphic) SHC using the Kubo formula and Berry curvatures. The component Inline graphic of the SHC tensor represents a spin current flowing along the Inline graphic-direction, polarized along the Inline graphic and an electric field applied along the Inline graphic-axis. The Kubo formula for the SHC is51,52:

graphic file with name M115.gif 18

where dynamic spin Berry curvature, velocity, and spin-current operators are defined as

graphic file with name M116.gif 19

and the static spin Berry curvature definition is

graphic file with name M117.gif 20

and

graphic file with name M118.gif 21
graphic file with name M119.gif 22

where Inline graphic while Inline graphic and Inline graphic are the Inline graphicDirac matrices52.

Results and discussion

The main results of the paper are discussed in this Section. In our computational calculations we considered a 500 Inline graphic 500 mesh points in the momentum space and Inline graphic meV. Figure 3 displays the EELS results under the influence of a staggered exchange field for varying values of Inline graphic and Inline graphic. The range considered for Inline graphic is between 0 and 0.5 eV, while we have considered two ratios for Inline graphic=1 or 1/3. In the case where Inline graphic (as shown in Fig. 3(a)), distinct peaks are observed, and as the strength of the field increases, the peaks shift towards higher energies. Conversely, for Inline graphic (depicted in Fig. 3 (b)), an opposite shift is observed for Inline graphic eV. To explore the entire spectrum of staggered and electric fields, contour plots of the EELS have been calculated within a specific energy and external field range (refer to Fig. 4). Notably, the majority of EELS behavior is associated with Inline graphic and Inline graphic eV. Comparing Fig. 4 (a) and 4 (c) reveals a similarity in the EELS response to positive values when both a staggered exchange field (Inline graphic) and an external electric field is applied.

Fig. 3.

Fig. 3

EELS obtained from Eq. (14) in presence of the staggered exchange field with (a) Inline graphic and (b) Inline graphic.

Fig. 4.

Fig. 4

Color density of the EELS in the presence of (a) the staggered exchange field with Inline graphic, (b) Inline graphic and (c) external electric field.

The optical conductivity of the PbBiI with external perturbations is computed using the Kubo formula. Due to the PbBiI’s isotropic nature, we focused on the optical conductivity along the Inline graphic-axis and omitted the Inline graphic-axis. In the pristine case, a peak in the real part of the optical conductivity aligns with the band gap energy (see Fig. 5 (a) and 5 (c)). Adjusting the Inline graphic and Inline graphic parameters alter the optical conductivity and shift peak energies. It is evident that regardless of the Inline graphic and Inline graphic ratio, introducing a staggered exchange field leads to new peaks in the real parts, with only their positions changing based on different ratios. Furthermore, due to the Kramers-Kronig relation, a dip in the imaginary parts occurs at the peak’s energy in the real parts (Fig. 5 (b) and 5 (d)).

Fig. 5.

Fig. 5

Real and imaginary parts of the optical conductivity for polarized light along the Inline graphic-axis by introducing staggered exchange field (a), (b) Inline graphic and (c), (d) Inline graphic.

Figure 6 showcases a contour plot illustrating the optical conductivity as a function of frequency, staggered exchange field (Fig. 6 (a)), and electric field (Fig. 6 (b)). It is evident from Fig. 6 (a) that the peak of the optical conductivity appears at an energy of 0.3 eV. When Inline graphic=0.3 eV, it causes a shift towards lower energies however, for Inline graphic 0.3 eV this trend is reversed. The external electric field also has a similar effect except in negative magnitudes.

Fig. 6.

Fig. 6

Color density of the real part of the optical conductivity in subject to the external perturbation (a) staggered exchange field ( Inline graphic) and (b) electric field.

The reflectivity is defined as the ratio of the intensity of reflected light to the intensity of incident light, typically expressed as a percentage. It is a key parameter in numerous applications, including optics, coatings, architecture, and solar energy technologies, where controlling and optimizing the reflective properties of materials is essential for achieving desired performance characteristics. Figure 7 is related to the reflectivity in the presence of the staggered exchange field. As we can see by increasing the photon’s frequency, we have an increase in the reflectivity and the peaks appear. In addition, by comparing Fig. 7 (a) and 7 (b) we found that reflectivity is greater in case Inline graphic.

Fig. 7.

Fig. 7

Reflectivity of the perturbed PbBiI in the presence of staggered exchange field (a) Inline graphic and (b) Inline graphic.

The 3D plot and color density of the spin Berry curvature of the PbBiI in the Brillouin zone are shown in Fig. 8 (a) and 8 (b) respectively. The Berry curvature is enhanced in locations where the energy difference between the bands gets reduced as in the anticrossing points. According to the figures, the Berry curvature is maximum around the Inline graphic point and decreases when moving away from this point. This is due to the existence of the band crossing near the Inline graphic point.

Fig. 8.

Fig. 8

Spin Berry curvature in the Brillouin zone around the Inline graphic point in the form of (a) color density and (b) surface plot.

The SHC can be expressed in terms of the spin Berry curvature (see Eq. (20)). Figure 9 (a) represents the dynamical SHC of the PbBiI versus frequency. Both the real and imaginary parts of the ac SHC are small. This suggests that to generate an ac spin current, one needs to use a magnetic field or magnetic materials.

Fig. 9.

Fig. 9

Calculated (a) real and imaginary parts of the dynamical SHC, (b) statical SHC as a function of temperature, and (c) statical SHC versus Fermi energy.

The dependence of the dc SHC on temperature is illustrated in Fig. 9 (b), however, a critical temperature of Inline graphic eV is identified, beyond which the SHC decreases sharply towards room temperature, reaching a minimum for Inline graphic eV. The Spin Hall conductivity of the PbBiI as a function of Fermi energy is plotted in Fig. 9 (c). The SHC has a quantized value within the topological band gap. Our calculations reveal that the SHC is minimal at Inline graphic and extremum at Inline graphic eV. This is because there are band crossings induced by spin-orbit interactions at these specific energies.

Conclusions

In summary, we have investigated the noncentrosymmetric system PbBiI where quantized spin Hall conductivity and Rashba spin-splitting coexist. Our analysis involved the computation of the Berry curvature and spin Hall conductivity, along with investigating the electronic and optical characteristics under external influences. By introducing staggered exchange and electric fields, we were able to manipulate the optical conductivity and EELS of the PbBiI. The peak of the real part of the optical conductivity is observed at 0.3 eV, with perturbations causing a shift towards lower energies. The Berry curvature reaches its maximum near the Inline graphic point where band crossing occurs, diminishing significantly further away from this region. Given the low dynamical spin Hall conductivity, a magnetic field is necessary to induce an a.c. spin current. Furthermore, the dc spin Hall conductivity exhibits critical behavior around Inline graphic eV. Also the spin-resolved optical conductivity could be one of the future research directions.

Acknowledgements

C. A. was supported by the Foundation for Polish Science project “MagTop” no. FENG.02.01-IP.05-0028/23 co-financed by the European Union from the funds of Priority 2 of theEuropean Funds for a Smart Economy Program 2021–2027 (FENG).

Author contributions

M. M. N proposed the subject and performed programming and writing and C. A contributed to formal analysis, writing - review & editing.

Data availability

The data that support the findings of this study areavailable from the corresponding author upon reasonablerequest.

Declarations

Competing interests

The authors declare no competing interests.

Footnotes

Publisher’s note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

The data that support the findings of this study areavailable from the corresponding author upon reasonablerequest.


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