First-principles and k·p study of strained HgTe shows linearly k-dependent higher-order C4 strain terms produce nontrivial sub-band splitting, explaining camel-back features and supporting a Weyl semimetal phase under compression.
Anisotropic sub-band splitting mechanisms in strained HgTe: a first principles study
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abstract
Mercury telluride is a canonical material for realizing topological phases, yet a full understanding of its electronic structure remains challenging due to subtle competing effects. Using first-principles calculations and $\mathbf{k}\cdot\mathbf{p}$ modelling, we study its topological phase diagram under strain. We show that linearly $k$-dependent higher-order $C_4$ strain terms are important for capturing the correct low-energy behaviour. These terms lead to a nontrivial $k$-dependence of the sub-band splitting arising from the interplay of strain and bulk inversion asymmetry. This explains the camel-back feature in the tensile regime and supports the emergence of a Weyl semimetal phase under compressive strain.
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cond-mat.mtrl-sci 1years
2024 1verdicts
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Anisotropic sub-band splitting mechanisms in strained HgTe: a first principles study
First-principles and k·p study of strained HgTe shows linearly k-dependent higher-order C4 strain terms produce nontrivial sub-band splitting, explaining camel-back features and supporting a Weyl semimetal phase under compression.