Nature Communications (Dec 2023)

Pressure-induced reversal of Peierls-like distortions elicits the polyamorphic transition in GeTe and GeSe

  • Tomoki Fujita,
  • Yuhan Chen,
  • Yoshio Kono,
  • Seiya Takahashi,
  • Hidetaka Kasai,
  • Davide Campi,
  • Marco Bernasconi,
  • Koji Ohara,
  • Hirokatsu Yumoto,
  • Takahisa Koyama,
  • Hiroshi Yamazaki,
  • Yasunori Senba,
  • Haruhiko Ohashi,
  • Ichiro Inoue,
  • Yujiro Hayashi,
  • Makina Yabashi,
  • Eiji Nishibori,
  • Riccardo Mazzarello,
  • Shuai Wei

DOI
https://doi.org/10.1038/s41467-023-43457-y
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 10

Abstract

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Abstract While polymorphism is prevalent in crystalline solids, polyamorphism draws increasing interest in various types of amorphous solids. Recent studies suggested that supercooling of liquid phase-change materials (PCMs) induces Peierls-like distortions in their local structures, underlying their liquid-liquid transitions before vitrification. However, the mechanism of how the vitrified phases undergo a possible polyamorphic transition remains elusive. Here, using high-energy synchrotron X-rays, we can access the precise pair distribution functions under high pressure and provide clear evidence that pressure can reverse the Peierls-like distortions, eliciting a polyamorphic transition in GeTe and GeSe. Combined with simulations based on machine-learned-neural-network potential, our structural analysis reveals a high-pressure state characterized by diminished Peierls-like distortion, greater coherence length, reduced compressibility, and a narrowing bandgap. Our finding underscores the crucial role of Peierls-like distortions in amorphous octahedral systems including PCMs. These distortions can be controlled through pressure and composition, offering potentials for designing properties in PCM-based devices.