Saved in:
Bibliographic Details
Main Authors: Deng, Liangzi, Zhang, Jianbo, Sakai, Yuki, Tang, Zhongjia, Adnani, Moein, Dahal, Rabin, Litvinchuk, Alexander P., Chelikowsky, James R., Cohen, Marvin L., Hemley, Russell J., Guloy, Arnold, Ding, Yang, Chu, Ching-Wu
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2401.09625
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916095990956032
author Deng, Liangzi
Zhang, Jianbo
Sakai, Yuki
Tang, Zhongjia
Adnani, Moein
Dahal, Rabin
Litvinchuk, Alexander P.
Chelikowsky, James R.
Cohen, Marvin L.
Hemley, Russell J.
Guloy, Arnold
Ding, Yang
Chu, Ching-Wu
author_facet Deng, Liangzi
Zhang, Jianbo
Sakai, Yuki
Tang, Zhongjia
Adnani, Moein
Dahal, Rabin
Litvinchuk, Alexander P.
Chelikowsky, James R.
Cohen, Marvin L.
Hemley, Russell J.
Guloy, Arnold
Ding, Yang
Chu, Ching-Wu
contents High-pressure studies on elements play an essential role in superconductivity research, with implications for both fundamental science and applications. Here we report the experimental discovery of surprisingly low pressure driving a novel germanium allotrope into a superconducting state in comparison to that for alpha-Ge. Raman measurements revealed structural phase transitions and possible electronic topological transitions under pressure up to 58 GPa. Based on pressure-dependent resistivity measurements, superconductivity was induced above 2 GPa and the maximum Tc of 6.8 K was observed under 4.6 GPa. Interestingly, a superconductivity enhancement was discovered during decompression, indicating the possibility of maintaining pressure-induced superconductivity at ambient pressure with better superconducting performance. Density functional theory analysis further suggested that the electronic structure of Ge (oP32) is sensitive to its detailed geometry and revealed that disorder in the beta-tin structure leads to a higher Tc in comparison to the perfect beta-tin Ge.
format Preprint
id arxiv_https___arxiv_org_abs_2401_09625
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Pressure-induced superconductivity in a novel germanium allotrope
Deng, Liangzi
Zhang, Jianbo
Sakai, Yuki
Tang, Zhongjia
Adnani, Moein
Dahal, Rabin
Litvinchuk, Alexander P.
Chelikowsky, James R.
Cohen, Marvin L.
Hemley, Russell J.
Guloy, Arnold
Ding, Yang
Chu, Ching-Wu
Superconductivity
High-pressure studies on elements play an essential role in superconductivity research, with implications for both fundamental science and applications. Here we report the experimental discovery of surprisingly low pressure driving a novel germanium allotrope into a superconducting state in comparison to that for alpha-Ge. Raman measurements revealed structural phase transitions and possible electronic topological transitions under pressure up to 58 GPa. Based on pressure-dependent resistivity measurements, superconductivity was induced above 2 GPa and the maximum Tc of 6.8 K was observed under 4.6 GPa. Interestingly, a superconductivity enhancement was discovered during decompression, indicating the possibility of maintaining pressure-induced superconductivity at ambient pressure with better superconducting performance. Density functional theory analysis further suggested that the electronic structure of Ge (oP32) is sensitive to its detailed geometry and revealed that disorder in the beta-tin structure leads to a higher Tc in comparison to the perfect beta-tin Ge.
title Pressure-induced superconductivity in a novel germanium allotrope
topic Superconductivity
url https://arxiv.org/abs/2401.09625