Copper ion diffusion by solid solution treatment advancing GeTe-based thermoelectrics

Chen, Yongqi; Li, Meng; Wang, Xiaodong; Chen, Wenyi; Liu, Siqi; Zhang, Min; Lyu, Wanyu; Li, Nanhai; Gao, Han; Liu, Weidi; Shi, Xiao-Lei; Chen, Zhi-Gang

Copper ion diffusion by solid solution treatment advancing GeTe-based thermoelectrics

Yongqi Chen, Meng Li (), Xiaodong Wang, Wenyi Chen, Siqi Liu, Min Zhang, Wanyu Lyu, Nanhai Li, Han Gao (), Weidi Liu, Xiao-Lei Shi and Zhi-Gang Chen ()
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Yongqi Chen: Queensland University of Technology
Meng Li: Queensland University of Technology
Xiaodong Wang: Queensland University of Technology
Wenyi Chen: Queensland University of Technology
Siqi Liu: Queensland University of Technology
Min Zhang: Queensland University of Technology
Wanyu Lyu: Queensland University of Technology
Nanhai Li: Queensland University of Technology
Han Gao: Queensland University of Technology
Weidi Liu: Queensland University of Technology
Xiao-Lei Shi: Queensland University of Technology
Zhi-Gang Chen: Queensland University of Technology

Nature Communications, 2025, vol. 16, issue 1, 1-10

Abstract: Abstract Coinage metals Cu and Ag are widely reckoned as effective dopants in thermoelectric materials due to their ability to optimise carrier concentration while preserving high carrier mobility, attributed to their inherent dynamic features. Traditionally, Cu/Ag ions are introduced through eutectic reactions, which inevitably result in interstitial doping. Here, we develop an innovative solid solution doping strategy that enables targeted doping, whereby Cu ions exclusively occupy host lattice sites rather than interstitial sites. By combining first-principles calculations with in-situ experiments, we demonstrate that this targeted doping approach relies on ion diffusion and induces lattice renormalisation, effectively reducing lattice defects and suppressing hole concentration. Consequently, the 1 at.% Cu doped Ge0.85Sb0.10Te sample exhibits an exceptional figure-of-merit of 2.3 at 775 K along with a desirable average value of 1.4 scoping 300 to 775 K. The power density of the corresponding single-leg thermoelectric module is 2.23 W·cm−2 under a temperature difference of 475 K. This work not only explains the kinetics behind dynamic doping behaviours, but also provide an original method to achieve high-quality functional materials with less lattice defects and a high carrier mobility.

Date: 2025
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DOI: 10.1038/s41467-025-62078-1

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