Creation, stabilization, and study at ambient pressure of   pressure-induced superconductivity in Bi$_{0.5}$Sb$_{1.5}$Te$_3$

Liangzi Deng (1); Busheng Wang (2); Clayton Halbert (3); Daniel J.; Schulze (1); Melissa Gooch (1); Trevor Bontke (1); Ting-Wei Kuo (1; 4),; Xin Shi (1); Shaowei Song (1); Nilesh Salke (5); Hung-Duen Yang (4); Zhifeng; Ren (1); Russell J. Hemley (3; 5; 6); Eva Zurek (2); Rohit P.; Prasankumar (7); Ching-Wu Chu (1) ((1) Department of Physics; Texas Center; for Superconductivity at the University of Houston (TcSUH); Houston; Texas,; USA; (2) Department of Chemistry; University at Buffalo; Buffalo; New York,; USA (3) Department of Chemistry; University of Illinois Chicago; Chicago,; Illinois; USA; (4) Department of Physics; National Sun Yet-Sen University,; Kaohsiung; Taiwan; (5) Department of Physics; University of Illinois Chicago,; Chicago; Illinois; USA; (6) Department of Earth; Environmental Sciences,; University of Illinois Chicago; Chicago; Illinois; USA; (7) Enterprise; Science Fund; Intellectual Ventures; Bellevue; Washington; USA)

arXiv:2502.01881·cond-mat.supr-con·February 5, 2025

Creation, stabilization, and study at ambient pressure of pressure-induced superconductivity in Bi$_{0.5}$Sb$_{1.5}$Te$_3$

Liangzi Deng (1), Busheng Wang (2), Clayton Halbert (3), Daniel J., Schulze (1), Melissa Gooch (1), Trevor Bontke (1), Ting-Wei Kuo (1, 4),, Xin Shi (1), Shaowei Song (1), Nilesh Salke (5), Hung-Duen Yang (4), Zhifeng, Ren (1), Russell J. Hemley (3, 5, 6), Eva Zurek (2)

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TL;DR

This study demonstrates the creation and stabilization of pressure-induced superconducting phases in Bi$_{0.5}$Sb$_{1.5}$Te$_3$ at ambient pressure, achieving record T$_c$ and revealing new physics through pressure-quench protocols and theoretical support.

Contribution

We developed a pressure-quench protocol to stabilize pressure-induced superconducting phases at ambient conditions in Bi$_{0.5}$Sb$_{1.5}$Te$_3$, enabling room-temperature retention and stability of these phases.

Findings

01

Superconducting phases in BST were stabilized at ambient pressure.

02

Record T$_c$ of 10.2 K achieved in BST.

03

Pressure-quench protocol preserves pressure-induced phases at room temperature.

Abstract

In light of breakthroughs in superconductivity under high pressure, and considering that record critical temperatures (T $_{c}$ s) across various systems have been achieved under high pressure, the primary challenge for higher Tc should no longer solely be to increase T $_{c}$ under extreme conditions but also to reduce, or ideally eliminate, the need for applied pressure in retaining pressure-induced or -enhanced superconductivity. The topological semiconductor Bi $_{0.5}$ Sb $_{1.5}$ Te $_{3}$ (BST) was chosen to demonstrate our approach to addressing this challenge and exploring its intriguing physics. Under pressures up to ~ 50 GPa, three superconducting phases (BST-I, -II, and -III) were observed. A superconducting phase in BST-I appears at ~ 4 GPa, without a structural transition, suggesting the possible topological nature of this phase. Using the pressure-quench protocol (PQP) recently…

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Taxonomy

TopicsPhysics of Superconductivity and Magnetism · Iron-based superconductors research · Magnetic and transport properties of perovskites and related materials