Unconventional Charge–Spin Conversion in Weyl‐Semimetal WTe<sub>2</sub>

Zhao, Bing; Karpiak, Bogdan; Khokhriakov, Dmitrii; Johansson, Annika; Hoque, Anamul Md; Xu, Xiaoming; Jiang, Yong; Mertig, Ingrid; Dash, Saroj P.

doi:10.1002/adma.202000818

Cited by 109 publications

(85 citation statements)

References 57 publications

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“…Such strong SOC materials usually are divided into two categories, heavy metals and quantum materials, for which the spin–charge interconversion is respectively attributed to the spin Hall effect (SHE) and the Rashba–Edelstein effect (REE), [ 1,2 ] or vice versa. Emergent topological quantum materials, including topological insulators (TIs), [ 3–6 ] Dirac semimetals, [ 7 ] and Weyl metals [ 8–11 ] —as the key core of quantum material families—have been compelling due to their order of magnitudes larger charge‐to‐spin conversion efficiencies compared to those in heavy metals. [ 12,13 ]…”

Section: Figurementioning

confidence: 99%

Visualizing Tailored Spin Phenomena in a Reduced‐Dimensional Topological Superlattice

Sun

Yang

et al. 2020

Advanced Materials

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Hall effect (SHE) and the Rashba-Edelstein effect (REE), [1,2] or vice versa. Emergent topological quantum materials, including topological insulators (TIs), [3-6] Dirac semimetals, [7] and Weyl metals [8-11]-as the key core of quantum material familieshave been compelling due to their order of magnitudes larger charge-to-spin conversion efficiencies compared to those in heavy metals. [12,13] While the spin-to-charge (SCC) efficiencies of most 3D TIs with a single surface state remain moderate, [14,15] the convergence of multiple nontrivial topological phases in one material, such as dual topological insulators, may suggest a new route for designing TI-based quantum materials. [16] Protected by both mirror symmetry and time reversal invariant symmetry, dual TIs would exhibit a high SCC efficiency benefiting from synergistic contributions of the coexisting TI phases. One prototypical example is (Bi 2-Bi 2 Se 3) N topological superlattices (N is the repeating unit number), categorized as one of an infinitely adaptive TI family series consisting of alternating one bismuth bilayer (Bi BL) and one quintuple bismuth selenide layer (Bi 2 Se 3 QL). [17] In

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Section: Figurementioning

confidence: 99%

Visualizing Tailored Spin Phenomena in a Reduced‐Dimensional Topological Superlattice

Sun

Yang

et al. 2020

Advanced Materials

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“…A magnetic field parallel to z causes spins to precess in the graphene plane but, according to and WTe 2 , including the persistent canted spin texture, 64 comparable results and efficiencies are expected in the latter, as borne out experimentally. 33,34,36 Our findings also call for a careful analysis of SHE measurements, since the interpretation of all-electrical detection in Hall bars 34,65,66 usually ignores the possibility of multiple spin Hall components. We show how the presence of canted SHE can be experimentally identified by reciprocal SHE, and how the different SHC contributions may be isolated in a spin precession setup.…”

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confidence: 85%

“…15,16 When thinned towards the monolayer limit, they transition from the type-II WSM bulk phase to the quantum spin Hall regime [17][18][19][20][21][22][23][24][25][26][27][28][29][30][31] with strain-tunable topological gap. 32 Recently, large charge-to-spin interconversion (CSI) generated by the spin Hall effect (SHE) has been reported in multilayers of MoTe 2 and WTe 2 [33][34][35][36] with evidence of long spin diffusion lengths (λ s ). 34 The efficiency of the SHE is characterized by the spin Hall angle (SHA, θ xy ) which indicates which fraction of a driving charge current can be converted into spin current; θ xy depends on the magnitude of SOC and is typically no more than a few percent at room temperature in heavy metals.…”

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confidence: 99%

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Charge-to-Spin Interconversion in Low-Symmetry Topological Materials

Vila¹,

Hsu²,

García³

et al. 2021

Preprint

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The spin polarization induced by the spin Hall eﬀect (SHE) in thin ﬁlms typically points out of the plane. This is rooted on the speciﬁc symmetries of traditionally studied systems, not in a fundamental constraint. Here, we show that the reduced symmetry of strong spin-orbit coupling materials such as MoTe2 or WTe2 enables a new form of canted spin Hall eﬀect (SHE), characterized by large and robust in-plane spin polarizations, which gives rise to an unprecedented charge-to-spin interconversion eﬀect. Through quantum transport calculations on realistic device geometries, including disorder, we found long spin diﬀusion lengths (λs) and a gate tunable charge-to-spin interconversion eﬃciency with an upper value reaching θxy ≈ 80%. The SHE ﬁgure of merit λsθxy ∼ 1–50 nm, can signiﬁcantly exceed values of conventional SHE materials, and stems from momentum-invariant (persistent) spin textures together with large spin Berry curvature along the Fermi contour. Speciﬁc guidelines for unambiguous experimental conﬁrmation are proposed, paving the way towards exploiting such phenomena in spintronic devices. These ﬁndings vividly emphasize how crystal symmetry and band topology can govern the intrinsic SHE, and how they may be exploited to broaden the range and eﬃciency of spintronic functionalities.

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“…For 2D MTACs‐based Dirac and Weyl semimetals, the most of the Weyl semimetals focus on the MoTe 2 and WTe 2 , which display tremendous potential in producing big spin current because they have the spin‐polarized states with topological protection and can carry a greatly big current density. [ 113–115 ] Zhang et al. [ 116 ] reported that WTe 2 is a type‐II Weyl semimetal that has two special transport properties observed in a 2D WTe 2 nanoribbon.…”

Section: Physical Propertiesmentioning

confidence: 99%

Two‐Dimensional Metal Telluride Atomic Crystals: Preparation, Physical Properties, and Applications

Tao

et al. 2021

Adv Funct Materials

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Atom‐thick 2D metal telluride atomic crystals (2D MTACs) display many fascinating physical properties for potential applications in multiple fields. In this review, recent advances in the preparation, physical properties and applications of 2D MTACs are presented. First, three kinds of the most available preparation methods for 2D single crystal MTACs have been summarized, including single crystal‐based mechanical exfoliation, molecular beam epitaxy, and chemical vapor deposition. Second, the recent progress on abundant physical properties of 2D MTACs is briefly introduced, including surface electronic properties, optoelectronic properties, electronic transport, and thermoelectric properties, ferroelectric properties, superconducting properties, and ferromagnetic properties. Third, the potential electronics, spintronics, optoelectronics and energy applications of 2D MTACs are presented. Finally, some significant challenges and opportunities in 2D MTACs are briefly addressed.

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Unconventional Charge–Spin Conversion in Weyl‐Semimetal WTe₂

Cited by 109 publications

References 57 publications

Visualizing Tailored Spin Phenomena in a Reduced‐Dimensional Topological Superlattice

Visualizing Tailored Spin Phenomena in a Reduced‐Dimensional Topological Superlattice

Charge-to-Spin Interconversion in Low-Symmetry Topological Materials

Two‐Dimensional Metal Telluride Atomic Crystals: Preparation, Physical Properties, and Applications

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Unconventional Charge–Spin Conversion in Weyl‐Semimetal WTe2

Cited by 109 publications

References 57 publications

Visualizing Tailored Spin Phenomena in a Reduced‐Dimensional Topological Superlattice

Visualizing Tailored Spin Phenomena in a Reduced‐Dimensional Topological Superlattice

Charge-to-Spin Interconversion in Low-Symmetry Topological Materials

Two‐Dimensional Metal Telluride Atomic Crystals: Preparation, Physical Properties, and Applications

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Unconventional Charge–Spin Conversion in Weyl‐Semimetal WTe₂