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Main Authors: Sharif, B. M., Theunissen, B., Westbrook, C., Steele, T., Choudhuri, S., Baumbach, R., Savrasov, S., Lederman, D.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.20076
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author Sharif, B. M.
Theunissen, B.
Westbrook, C.
Steele, T.
Choudhuri, S.
Baumbach, R.
Savrasov, S.
Lederman, D.
author_facet Sharif, B. M.
Theunissen, B.
Westbrook, C.
Steele, T.
Choudhuri, S.
Baumbach, R.
Savrasov, S.
Lederman, D.
contents We demonstrate epitaxial growth of copper selenide (Cu$_{2-x}$Se) thin films in both cubic and rhombohedral phases, achieved via molecular beam epitaxy on Al$_2$O$_3$ (001) substrates. Remarkably, the high-temperature cubic phase -- which in bulk transforms into the rhombohedral structure below 400 K -- is stabilized at room temperature and below, well outside its bulk equilibrium stability range. In the cubic phase films, temperature-dependent electrical transport reveals a pronounced, hysteretic resistivity peak near 140 K, accompanied by unit cell doubling along the [111] direction, as observed by x-ray diffraction, which are hallmarks of a charge density wave (CDW) transition. First-principles calculations show strong Fermi surface nesting in the cubic phase, consistent with the observed CDW instability. In contrast, the rhombohedral films exhibit suppressed nesting and no structural modulation. These results not only unambiguously identify a previously unreported CDW in Cu$_{2-x}$Se thin films, but also establish an epitaxial platform for tuning emergent electronic phases via strain and interface engineering.
format Preprint
id arxiv_https___arxiv_org_abs_2506_20076
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Epitaxial Stabilization and Emergent Charge Order in Copper Selenide Thin Films
Sharif, B. M.
Theunissen, B.
Westbrook, C.
Steele, T.
Choudhuri, S.
Baumbach, R.
Savrasov, S.
Lederman, D.
Materials Science
We demonstrate epitaxial growth of copper selenide (Cu$_{2-x}$Se) thin films in both cubic and rhombohedral phases, achieved via molecular beam epitaxy on Al$_2$O$_3$ (001) substrates. Remarkably, the high-temperature cubic phase -- which in bulk transforms into the rhombohedral structure below 400 K -- is stabilized at room temperature and below, well outside its bulk equilibrium stability range. In the cubic phase films, temperature-dependent electrical transport reveals a pronounced, hysteretic resistivity peak near 140 K, accompanied by unit cell doubling along the [111] direction, as observed by x-ray diffraction, which are hallmarks of a charge density wave (CDW) transition. First-principles calculations show strong Fermi surface nesting in the cubic phase, consistent with the observed CDW instability. In contrast, the rhombohedral films exhibit suppressed nesting and no structural modulation. These results not only unambiguously identify a previously unreported CDW in Cu$_{2-x}$Se thin films, but also establish an epitaxial platform for tuning emergent electronic phases via strain and interface engineering.
title Epitaxial Stabilization and Emergent Charge Order in Copper Selenide Thin Films
topic Materials Science
url https://arxiv.org/abs/2506.20076