From stoichiometric to off-stoichiometric GeTe: Phase diagram reconstruction and thermoelectric performance reassessment

Yi Fen Tsai, Ying Chun Chao, Cheng Rong Hsing, Kuang Kuo Wang, Yung Hsiang Tung, Chun Chuen Yang, Sinn Wen Chen, G. Jeffrey Snyder, Hung Wei Yen, Ching Ming Wei, Pai Chun Wei, Hsin Jay Wu

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Abstract

This study investigates the structure, microstructure, and transport properties of off-stoichiometric GeTe (off-GeTe). In a narrow range of 50–53 at% Te, both the rhombohedral a-GeTe and orthorhombic g-GeTe phases coexist. Despite their similar chemical composition, GeTe and off-GeTe alloys exhibit distinct microstructural and thermal/electronic properties. Theoretical density functional theory (DFT) calculations were employed to verify that changes in the Ge/Te ratios influence the concentration of Ge vacancies, leading to a significant alteration in transport properties despite minor variations in chemical compositions. The off-GeTe alloy, which is free of Ge precipitates, displays defective domain boundaries, showcasing a non-typical herringbone nanostructure that is unprecedented for GeTe-based materials. Notably, the phase transition temperature of off-GeTe, at 620K, differs from its peak zT temperature of 698K. Moreover, a TE device incorporating off-GeTe demonstrates superior interfacial stability and higher energy conversion efficiency compared to its stoichiometric GeTe counterpart. Consequently, off-GeTe demonstrates superior TE performance and enhanced interfacial stability compared to stoichiometric GeTe. The addition of Sb to off-GeTe further improves its potential for TE applications by lifting the single-leg conversion efficiency greater than 3%.

Original languageEnglish
Article number119644
JournalActa Materialia
Volume265
DOIs
StatePublished - 15 Feb 2024

Keywords

  • Defective domain boundaries
  • Off-stoichiometric GeTe
  • Theoretical density functional theory (DFT)
  • Thermoelectric

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