Near stoichiometric-ratio Mg3Sb2 thermoelectric thin films fabricated via multi-step annealing strategies

IF 10 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Today Physics Pub Date : 2024-09-14 DOI:10.1016/j.mtphys.2024.101552

Qi Zou , Hongjing Shang , Zhongxin Liang , Lin Zhang , Xiaolei Wang , Yutong Chen , Changping Feng , Hongwei Gu , Zhifeng Ren , Fazhu Ding

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引用次数: 0

Abstract

Recently, Zintl Mg₃Sb₂-based compounds have attracted attention due to high thermoelectric performance, but most studies are concentrated on bulk materials with few on films and devices, limiting their applications for microelectronics. Here, p-type Mg₃Sb₂ films near stoichiometric-ratio are successfully fabricated using the multi-step experimental strategies based on the magnetron sputtering method. By tuning the energy structure and carrier transport, their thermoelectric performance is significantly improved, with a power factor up to 258.64 μW m⁻¹ K⁻² at ∼623 K. A Mg₃Sb₂-based generator is fabricated using these films, representing the first report of such a device. The output performance of this generator is evaluated and its power density is found to reach 9.4 μW cm⁻² at ΔT of 40 K, showing good potential for powering electronics. Furthermore, the generator shows good stability with no significant change in output properties after storage in air for 40 days or over periodic cycles of high- and room-temperature operation.

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通过多步退火策略制造的接近化学计量比的 Mg3Sb2 热电薄膜

近年来，基于 Zintl Mg3Sb2 的化合物因其热电性能高而备受关注，但大多数研究都集中在块体材料上，很少涉及薄膜和器件，从而限制了其在微电子领域的应用。本文采用基于磁控溅射法的多步骤实验策略，成功制备了接近化学计量比的 p 型 Mg3Sb2 薄膜。通过调整能量结构和载流子传输，这些薄膜的热电性能得到了显著提高，在 623 K 时功率因数高达 258.64 μW m-1 K-2。对这种发生器的输出性能进行了评估，发现其功率密度在ΔT为40 K时达到9.4 μW cm-2，显示出为电子设备供电的良好潜力。此外，这种发生器还显示出良好的稳定性，在空气中储存 40 天或在高温和室温运行的周期性循环中，其输出特性没有发生显著变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Materials Today Physics Materials Science-General Materials Science

CiteScore

14.00

自引率

7.80%

发文量

284

审稿时长

15 days

期刊介绍： Materials Today Physics is a multi-disciplinary journal focused on the physics of materials, encompassing both the physical properties and materials synthesis. Operating at the interface of physics and materials science, this journal covers one of the largest and most dynamic fields within physical science. The forefront research in materials physics is driving advancements in new materials, uncovering new physics, and fostering novel applications at an unprecedented pace.