同时优化 Mn3Pt 棒钙化合物中的熵变和热滞后

IF 4.3 2区 材料科学 Q2 CHEMISTRY, PHYSICAL
Xueting Zhao , Kun Zhang , Peng Liu , Qing Guo , Haoyu Wang , Yuanwen Feng , Bing Li
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引用次数: 0

摘要

Mn3Pt 金属化合物具有较高的热导率和压力敏感性,因此有望应用于巴氏冷却。然而,它们受到低熵变和大热滞后的限制。本研究调查了掺杂碳(C)和氮(N)以及取代锗(Ge)对 Mn3Pt 结构的影响,以及热效应和巴焦效应。与此相反,Ge 取代提高了相变温度,并将熵变提高了 123%,Mn3Pt0.8Ge0.2 实现了 22.7 J kg-1 K-1 的最大熵变。此外,还引入了缺陷以降低相变成核驱动力,从而将热滞后降低到 4 K。这项工作为同时优化熵变和热滞后提供了一种策略,推动了高效可调巴焦材料的发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simultaneous optimization of entropy changes and thermal hysteresis in barocaloric compound of Mn3Pt
Mn3Pt metal compounds are promising candidates for barocaloric cooling applications for their high thermal conductivity and pressure sensitivity. However, they are constrained by low entropy change and large thermal hysteresis. This study investigates the effects of doping with carbon (C) and nitrogen (N) and substituting with germanium (Ge) on the structure, as well as the thermal and barocaloric effects of Mn3Pt. We found that N and C doping significantly reduces the phase transition temperature and improves pressure sensitivity, although at the cost of reduced entropy change. In contrast, Ge substitution increases the phase transition temperature and enhances the entropy change by 123 %, with Mn3Pt0.8Ge0.2 achieving a maximum entropy change of 22.7 J kg−1 K−1. Additionally, defects were introduced to reduce the phase transition nucleation driving force, thereby lowering the thermal hysteresis to 4 K. This work provides a strategy for the simultaneous optimization of entropy change and thermal hysteresis, advancing the development of efficient and tunable barocaloric materials.
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来源期刊
Intermetallics
Intermetallics 工程技术-材料科学:综合
CiteScore
7.80
自引率
9.10%
发文量
291
审稿时长
37 days
期刊介绍: This journal is a platform for publishing innovative research and overviews for advancing our understanding of the structure, property, and functionality of complex metallic alloys, including intermetallics, metallic glasses, and high entropy alloys. The journal reports the science and engineering of metallic materials in the following aspects: Theories and experiments which address the relationship between property and structure in all length scales. Physical modeling and numerical simulations which provide a comprehensive understanding of experimental observations. Stimulated methodologies to characterize the structure and chemistry of materials that correlate the properties. Technological applications resulting from the understanding of property-structure relationship in materials. Novel and cutting-edge results warranting rapid communication. The journal also publishes special issues on selected topics and overviews by invitation only.
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