Different shapes of spin textures as a journey through the Brillouin zone

Acosta, Carlos Mera; Yuan, Lin-Ding; Dalpian, Gustavo M.; Zunger, Alex

doi:10.1103/physrevb.104.104408

Cited by 34 publications

(43 citation statements)

References 55 publications

(61 reference statements)

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“…Nevertheless, the linear-in-k spin arrangement at the high-symmetry points can be predicted with the help of the group theory and further verified by the DFT calculations. Following the study by Mera Acosta et al, 26 we note that the crystallographic point group D 6 describing TaSi 2 may yield the purely radial Weyl spin texture at the k-vectors possessing the point group symmetry D 3 or D 6 . Using the Bilbao Crystallographic Server, 47,48 we determined little point groups of all the high-symmetry points (Γ, A, K, H and M ) and we found that most of them can be the 'source' or 'sink' of the ra-dial spin texture.…”

Section: Current-induced Spin Accumulation For Arbitrary Socmentioning

confidence: 80%

“…25 In order to establish a link between CISS and the unconventional spin accumulation, quantitative studies of different chiral crystals are required, including those with complex spin textures, where different types of SOC might be simultaneously present in the momentum space. 26 Before starting the analysis of specific materials, let us briefly overview the computational approach allowing the calculation of the spin accumulation for arbitrary SOC. The equilibrium electron distribution in a crystal can be described by the Fermi distribution function f 0 k .…”

Section: Current-induced Spin Accumulation For Arbitrary Socmentioning

confidence: 99%

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Long-range current-induced spin accumulation in chiral crystals

Roy¹,

Cerasoli²,

Jayaraj³

et al. 2022

Preprint

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The chirality-induced spin selectivity (CISS) refers to a conversion between charge and spin currents occurring in chiral molecules and solids, which reveals a great potential for applications in various areas of technology. Nevertheless, after two decades of studies, the understanding of its microscopic origin remains elusive. Here, the CISS effect in materials with strong spin-orbit coupling is explained in terms of the unconventional current-induced spin accumulation, an analog of the Rashba-Edelstein effect that may manifest in systems with a radial spin texture reversing the sign for opposite enantiomers. The calculations of spin accumulation based on the density functional theory, performed for the first time for Te and TaSi2, provide a rationale for the experimental studies reporting CISS in these materials. The analysis of a general Weyl-type spin-orbit coupling locally describing the spin texture at specific momentum vectors, reveals that a quasi-persistent spin helix emerges in the real space as a consequence of the crystal symmetries, and prevents the spins from decoherence, which qualitatively supports the observation of the long-range spin transport in CISS experiments. These results open the perspectives for DFT calculations of CISS for any chiral crystals and represent a step forward to its understanding in general systems.

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Section: Current-induced Spin Accumulation For Arbitrary Socmentioning

confidence: 80%

Section: Current-induced Spin Accumulation For Arbitrary Socmentioning

confidence: 99%

Long-range current-induced spin accumulation in chiral crystals

Roy¹,

Cerasoli²,

Jayaraj³

et al. 2022

Preprint

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“…These SS prototypes are also characterized by different spin textures, i.e., the SP pattern in the reciprocal space (Figure 1). 29 We propose and implement a two-step automatic design of material properties: i) target property prediction based on the…”

Section: Background and Summarymentioning

confidence: 99%

“…In addition to the common DPs previously defined, the Rashba SS in 2D compounds also requires a non-zero electric dipole (allowed by at least one polar atomic site and local dipoles that add up to non-zero, as described by 35). The SS type depends on the wave vector point group 29 and hence, the DPs also include the k-point preserving the time-reversal symmetry, as well as a linear-in-k shift. The unique DPs for the Rashba SS (i.e., non-zero electric dipoles, time-reversal symmetry, and linear-in-k SS) are illustrated in the purple quadrant of Figure 2.…”

Section: /506mentioning

confidence: 99%

“…Note that a given compound can present more than one SS prototype at different k-points, as discussed by Acosta at al. 29 , and thus the SS characterization should identify all SS types in a given compound. As both the Rashba and Dresselhaus SS prototypes share the common characteristic of having linear-in-k Hamiltonians, it will be useful to label them as a Linear SS (LSS) when implementing the SS identification algorithm, as described below, while not losing the symmetry criteria that differentiate them.…”

Section: /506mentioning

confidence: 99%

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High throughput inverse design and Bayesian optimization of functionalities: spin splitting in two-dimensional compounds

Nascimento¹,

Ogoshi²,

Fazzio³

et al. 2022

Preprint

Self Cite

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The development of spintronic devices demands the existence of materials with some kind of spin splitting (SS). In this Data Descriptor, we build a database of ab initio calculated SS in 2D materials. More than that, we propose a workflow for materials design integrating an inverse design approach and a Bayesian inference optimization. We use the prediction of SS prototypes for spintronic applications as an illustrative example of the proposed workflow. The prediction process starts with the establishment of the design principles (the physical mechanism behind the target properties), that are used as filters for materials screening, and followed by density functional theory (DFT) calculations. Applying this process to the C2DB database, we identify and classify 358 2D materials according to SS type at the valence and/or conduction bands. The Bayesian optimization captures trends that are used for the rationalized design of 2D materials with the ideal conditions of band gap and SS for potential spintronics applications. Our workflow can be applied to any other material property.

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A Unified Understanding of Diverse Spin Textures of Kramers–Weyl Fermions in Nonmagnetic Chiral Crystals

Tan

Jiang

et al. 2022

Adv Funct Materials

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Chiral crystals, characterized by rotation, screw rotation, and translation symmetries are abundant in nature. The existence of Kramers–Weyl fermions (KWFs) at the time‐reversal‐invariant momenta in nonmagnetic chiral crystals (NCCs) has attracted intense attention due to their unique physical properties beyond conventional Weyl fermions. Although the spin texture, one of the most fundamental physical quantities, is found to be dramatically different for different KWFs in different NCCs, a unified understanding of this puzzling phenomenon is still lacking. In this article, combining k · p theory and first‐principles calculations, k‐linear Hamiltonians for KWFs are constructed and consequently a complete classification for the spin textures of KWFs in all the NCCs is made, which are confirmed by a series of material example calculations. Interestingly, it is found that the spin textures are reversed in NCCs with opposite chirality, leading to reversed Fermi arc surface states. Importantly, this study unveils that the nonlinear optical responses around the KWFs in NCCs can be largely determined by their spin texture classification. This study not only provides a unified understanding of the spin textures of KWFs in all the NCCs, but also suggests a principle to design novel KWF‐related spintronics and nonlinear optics.

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Different shapes of spin textures as a journey through the Brillouin zone

Cited by 34 publications

References 55 publications

Long-range current-induced spin accumulation in chiral crystals

Long-range current-induced spin accumulation in chiral crystals

High throughput inverse design and Bayesian optimization of functionalities: spin splitting in two-dimensional compounds

A Unified Understanding of Diverse Spin Textures of Kramers–Weyl Fermions in Nonmagnetic Chiral Crystals

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