材料科学
零(语言学)
复合材料
热膨胀
Laves相
热的
热力学
金属间化合物
物理
合金
哲学
语言学
作者
He Wang,Yihan Wang,Yuanyuan Gong,Guizhou Xu,Erjia Liu,Xuefei Miao,Yujing Zhang,Yanyan Shao,Jun Liu,Najam UI Hassan,Ishfaq Ahmad Shah,Feng Xu
出处
期刊:Rare Metals
[Springer Science+Business Media]
日期:2024-07-09
卷期号:43 (12): 6596-6605
被引量:9
标识
DOI:10.1007/s12598-024-02867-7
摘要
Abstract MgZn 2 ‐type (Hf,Ta)Fe 2 , known for its negative thermal expansion during magnetic transition, is a key component in the production of zero thermal expansion composites. This paper presents a basic approach for designing such composites by introducing an additional Laves phase through atomic substitution. Specifically, Co, Ni, Al and V were chosen to substitute Fe in (Hf,Ta)Fe 2 . The addition of Co or Ni results in the creation of an extra MgCu 2 (C15) phase in the MgZn 2 (C14) matrix. The C15 phase exhibits positive thermal expansion, which effectively compensates for the negative thermal expansion of the C14 matrix. By adjusting the amount of Co or Ni, zero thermal expansion can be achieved in a given temperature range. Meanwhile, the replacement of Fe by Al or V yields another C14 phase with a higher doping element content relative to the C14 matrix. These two C14 phases possess different magnetic transition temperatures and negative thermal expansion temperature regions. The combination of the two C14 phases results in zero thermal expansion due to the effective thermal expansion compensation between them. Our results serve to identify potential approaches for designing (Hf,Ta)Fe 2 ‐based zero thermal expansion composites.
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