通过氢化物冷等静压和无压烧结制备的TiTaNbZrHf高熵合金的烧结、微观结构及力学性能

Sintering, Microstructure, and Mechanical Properties of TiTaNbZrHf High-Entropy Alloys Prepared by Cold Isostatic Pressing and Pressure-Less Sintering of Hydrides.

作者信息

Chen Yubing, Liu Peidong, Dong Zhaowang, Liu Hanning, Wang Junjie, Guo Xueyi, Xia Yang, Wang Qinmeng

机构信息

School of Metallurgy and Environment, Central South University, Changsha 410083, China.

National and Regional Joint Engineering Research Center of Nonferrous Metal Resources Recycling, Changsha 410083, China.

出版信息

Materials (Basel). 2023 Feb 21;16(5):1759. doi: 10.3390/ma16051759.

DOI:10.3390/ma16051759

PMID:36902877

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10003928/

Abstract

A TiTaNbZrHf refractory high-entropy alloy (RHEA) was synthesized through a cold isostatic pressing and a pressure-less sintering process in a hydrogen atmosphere using a powder mixture of metal hydride prepared either by mechanical alloying (MA) or by rotating mixing. This study investigates how differences in powder particle sizes impact the RHEA's microstructure and mechanical properties. HCP (a = b = 3.198 Å, c = 5.061 Å) and BCC2 (a = b = c = 3.40 Å) phases were observed in the microstructure of coarse powder TiTaNbZrHf RHEAs at 1400 °C. In contrast, fine powder RHEAs were found to possess two-phase structures of HCP and BCC1 (a = b = c = 3.36 Å) with a higher hardness of 431 HV, compression strength of 1620 MPa, and a plasticity of >20%.

摘要

通过冷等静压和在氢气气氛中无压烧结工艺，使用通过机械合金化（MA）或旋转混合制备的金属氢化物粉末混合物，合成了一种TiTaNbZrHf难熔高熵合金（RHEA）。本研究调查了粉末粒度差异如何影响RHEA的微观结构和力学性能。在1400℃下，粗粉末TiTaNbZrHf RHEA的微观结构中观察到HCP（a = b = 3.198 Å，c = 5.061 Å）和BCC2（a = b = c = 3.40 Å）相。相比之下，发现细粉末RHEA具有HCP和BCC1（a = b = c = 3.36 Å）的两相结构，硬度更高，为431 HV，抗压强度为1620 MPa，塑性>20%。