Crystal Symmetry Modification Enables High-ranged In-plane Thermoelectric Performance in N-type SnSe Crystals

Overview

Journal Nat Commun

Specialty Biology

Date 2025 Feb 20

PMID 39979348

Authors

Haonan Shi

Yi Wen

Shulin Bai

Cheng Chang

Lizhong Su

Tian Gao

Shibo Liu

Dongrui Liu

Bingchao Qin

Yongxin Qin

Huiqiang Liang

Xin Qian

Zhenghao Hou

Xiang Gao

Tianhang Zhou

Qing Tan

Li-Dong Zhao

Affiliations

Soon will be listed here.

Abstract

SnSe crystal has witnessed significant advancements as a promising thermoelectric material over the past decade. Its in-plane direction shows robust mechanical strength for practical thermoelectric applications. Herein, we optimize the in-plane thermoelectric performance of n-type SnSe by crystal symmetry modification. In particular, we find that Te and Mo alloying continuously enhances the crystal symmetry, thereby increasing the carrier mobility to ~ 422 cmV s. Simultaneously, the conduction bands converge with the symmetry modification, further improving the electrical transport. Additionally, the lattice thermal conductivity is limited to ~ 1.1 W m K due to the softness of both acoustic and optical branches. Consequently, we achieve a power factor of ~ 28 μW cm K and ZT of ~ 0.6 in n-type SnSe at 300 K. The average ZT reaches ~ 0.89 at 300-723 K. The single-leg device based on the obtained n-type SnSe shows a remarkable efficiency of ~ 5.3% under the ΔT of ~ 300 K, which is the highest reported in n-type SnSe. This work demonstrates the substantial potential of SnSe for practical applications of power generation and waste heat recovery.

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