Towards topological quasifreestanding stanene via substrate engineering

Sante, Domenico Di; Eck, Philipp; Bauernfeind, Maximilian; Will, Marius; Thomale, Ronny; Schäfer, J.; Claessen, R.; Sangiovanni, Giorgio

doi:10.1103/physrevb.99.035145

Cited by 22 publications

(13 citation statements)

References 66 publications

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“…[85] While the intrinsic band structures of all higher-Z Xenes are predicted to be similar to that of graphene, [85,90,106,[112][113][114][115] the increased orbital overlap due to buckling contributes to a slight increase in the SO gap. [85] As a consequence of their orbital structure, QSH behavior in Xenes may be tuned by orbital hybridization (for example, via substrate interactions [116,117] ), or induced by lattice strain, [105] as well as by chemical functionalization with impurities or functional groups. [90,118] In buckled stanene, for example, compressive strain leads to an increase of the p x,y + orbital energy above the Fermi level at Γ, rendering the material metallic.…”

Section: Graphene and Group Iva Buckled Honeycomb Latticesmentioning

confidence: 99%

Atomically Thin Quantum Spin Hall Insulators

et al. 2021

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Atomically thin topological materials are attracting growing attention for their potential to radically transform classical and quantum electronic device concepts. Among them is the quantum spin Hall (QSH) insulator—a 2D state of matter that arises from interplay of topological band inversion and strong spin–orbit coupling, with large tunable bulk bandgaps up to 800 meV and gapless, 1D edge states. Reviewing recent advances in materials science and engineering alongside theoretical description, the QSH materials library is surveyed with focus on the prospects for QSH‐based device applications. In particular, theoretical predictions of nontrivial superconducting pairing in the QSH state toward Majorana‐based topological quantum computing are discussed, which are the next frontier in QSH materials research.

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Section: Graphene and Group Iva Buckled Honeycomb Latticesmentioning

confidence: 99%

Atomically Thin Quantum Spin Hall Insulators

et al. 2021

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“…To understand the proximity effect on the electronic band structure of graphene, we first introduce a generic phenomenological model describing Dirac states of graphene with reduced symmetry due to external effects. [ 17,18,20,62,63,64,65,66 ] The model Hamiltonian given in the basis

| {normalΨ}_{normalA}, ↑ ⟩

| {normalΨ}_{normalA}, ↓ ⟩

| {normalΨ}_{normalB}, ↑ ⟩

, and

| {normalΨ}_{normalB}, ↓ ⟩

reads

H = {scriptH}_{0} + {scriptH}_{normalΔ} + {scriptH}_{normalI} + {scriptH}_{normalR} + {scriptH}_{PIA} + E_{D}

{scriptH}_{0} = ℏ v_{normalF} (τ k_{x} σ_{x} - k_{y} σ_{y}) \otimes s_{0}

{scriptH}_{normalΔ} = Δ σ_{z} \otimes s_{0}

{scriptH}_{normalI} = τ (λ_{normalI}^{normalA} σ_{+} + λ_{normalI}^{normalB} σ_{-}) \otimes s_{z}

{scriptH}_{normalR} = - λ_{normalR} (τ σ_{x} \otimes s_{y} + σ_{y} \otimes s_{x})

scrip...

…”

Section: Monolayer Graphene In Proximity To Bi2se3 and Bi2te3mentioning

confidence: 99%

Heterostructures of Graphene and Topological Insulators Bi₂Se₃, Bi₂Te₃, and Sb₂Te₃

Zollner

Fabian

2020

Physica Status Solidi (b)

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Prototypical 3D topological insulators of the Bi2Se3 family provide a beautiful example of the appearance of the surface states inside the bulk bandgap caused by spin‐orbit coupling‐induced topology. The surface states are protected against backscattering by time reversal symmetry, and exhibit spin‐momentum locking whereby the electron spin is polarized perpendicular to the momentum, typically in the plane of the surface. In contrast, graphene is a prototypical 2D material, with negligible spin‐orbit coupling. When graphene is placed on the surface of a topological insulator, giant spin‐orbit coupling is induced by the proximity effect, enabling interesting novel electronic properties of its Dirac electrons. A detailed theoretical study of the proximity effects of monolayer graphene and topological insulators Bi2Se3, Bi2Te3, and Sb2Te3 is presented, and the appearance of the qualitatively new spin‐orbit splittings, well described by a phenomenological Hamiltonian, is elucidated by analyzing the orbital decomposition of the involved band structures. This should be useful for building microscopic models of the proximity effects between the surfaces of the topological insulators and graphene.

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“…Through the above analysis, the main reasons for the attractive application prospect of Xenes in the field of electrochemistry are summarized as follows: 1) a large surface-active site density can be contributed by high surface to bulk ratios for impressive applications in the surface-involving reactions, [148] and electrode-electrolyte accessibilities can also be promoted with remarkably highmaterial utilization; [149][150][151] 2) Xenes endows a successive and shortening ion/electron channel, which can improve ion/electron conductivities [152][153][154] and secure fast reaction kinetics; [142,155] 3) the increased interlayer spacing provides enough large interspaces to buffer the volumetric expansion during electrochemical reactions; 4) considering alloying reaction mechanism of group IV and group V Xenes, they must own ultrahigh specific capacities for alkaline ion batteries; [102,153,[156][157][158] 5) Xenes with strong flexibility can self-relieve the volume expansion and structural deformation at a large degree during the electrochemical reactions; [54,159] 6) Xenes with excellent mechanical properties as protective films to cover the current collector, have enough high strength to restrain growth of metal dendrites; 7) the physicochemical properties of Xenes are easily adjusted due to the surface exposed lone pair electrons, which give them with vivid electrochemical reactivities and flexibilities of various chemical functionalities; 8) Xenes as block unites can be used to construct various fantastic micro-/ nano-structures [115,[160][161][162] for various amazing applications; 9) relatively simple atomic arrangement, which enables easy investigation and modeling for exploring the novel mechanism in the related application. [26,163] In summary, Xenes are considered to be the star material in future electrochemical applications with high capacity, high speed, high safety, and flexibility due to its unique structure, electronic and other characteristics.…”

Section: Why Xenes Are Important In Fundamental Electrochemistry?mentioning

confidence: 99%

Xenes as an Emerging 2D Monoelemental Family: Fundamental Electrochemistry and Energy Applications

Wang

Kou

et al. 2020

Adv Funct Materials

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As an emerging subclass of 2D materials, Xenes (e.g., borophene, silicene, germanene, stanene, phosphorene, arsenene, antimonene, and bismuthene) consist of one single element and have opened the door for various important applications. Benefiting from their impressive characteristics, including ultrathin folded structure, ultrahigh surface–volume ratio, excellent mechanical strength and flexibility, Xenes are considered as promising electrode materials in the field of electrochemical energy with large capacity, high rate, and high safety. This review provides a comprehensive summary of selected properties, synthetic challenges, and the latest theoretical and experimental advances in the energy‐related applications of Xenes, including Li/Na ion batteries, Li–S batteries, electrocatalysis, and supercapacitors. Finally, the challenges and outlook of this emerging field are discussed.

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Towards topological quasifreestanding stanene via substrate engineering

Cited by 22 publications

References 66 publications

Atomically Thin Quantum Spin Hall Insulators

Atomically Thin Quantum Spin Hall Insulators

Heterostructures of Graphene and Topological Insulators Bi₂Se₃, Bi₂Te₃, and Sb₂Te₃

Xenes as an Emerging 2D Monoelemental Family: Fundamental Electrochemistry and Energy Applications

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Towards topological quasifreestanding stanene via substrate engineering

Cited by 22 publications

References 66 publications

Atomically Thin Quantum Spin Hall Insulators

Atomically Thin Quantum Spin Hall Insulators

Heterostructures of Graphene and Topological Insulators Bi2Se3, Bi2Te3, and Sb2Te3

Xenes as an Emerging 2D Monoelemental Family: Fundamental Electrochemistry and Energy Applications

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Heterostructures of Graphene and Topological Insulators Bi₂Se₃, Bi₂Te₃, and Sb₂Te₃