What question did this study set out to answer?

The study aims to discover new topological phases in bismuth halides through pressure application.

March 22, 2026

Pressure-Induced Discovery of a Topological Phase of Bi 4 Br 4 with AA′′-Stacking

Key Points

The study aims to discover new topological phases in bismuth halides through pressure application.
Utilized CALYPSO structure searches for predicting stable phases under pressure.
Performed first-principles enthalpy ranking for stability assessments.
Examined the pressure-induced transition from β-Bi4Br4 to the new C2/m-AA″ phase.
Discovered a stable C2/m-AA″ phase of Bi4Br4 at pressures above 4 GPa, persisting to at least 15 GPa.
Identified an imaginary phonon mode in β-Bi4Br4 under compression, explaining the transition process.
Characterized the C2/m-AA″ phase as a weak topological insulator with gapless surface states.

Abstract

Bismuth halides Bi4X4 (X = Br, I) consist of quasi-one-dimensional van der Waals chains whose interchain stacking can be reshaped by pressure, potentially reprogramming topology. Using CALYPSO structure searches with first-principles enthalpy ranking, we uncover a previously unreported C2/m phase of Bi4Br4 featuring a novel AA″ stacking that becomes stable above ∼4 GPa and persists to at least 15 GPa. We map the transformation from known β-Bi4Br4 (AA stacking): under compression β develops an imaginary phonon mode, appears as a first-order saddle point in the crystal-solution landscape, and relaxes into the C2/m-AA″ structure with an estimated barrier of ∼40 meV/atom, explaining pressure-driven stacking rearrangement. With spin-orbit coupling, a band gap opens at symmetry crossings and a nontrivial inversion yields Z2 = (001; 0), identifying the AA″ phase as a weak topological insulator with gapless (100)/(010) surface states.

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Cite This Study

Li et al. (Thu,) studied this question.

synapsesocial.com/papers/69bf8641f665edcd009e8d94 https://doi.org/https://doi.org/10.1021/acs.jpclett.6c00232

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