Effect of Cr/Mn Addition in TiVNb on Hydrogen Sorption Properties: Thermodynamics and Phase Transition Study

Hydrogen Pub Date : 2024-02-18 DOI:10.3390/hydrogen5010008

A. Bouzidi, Erik Elkaim, Vivian Nassif, C. Zlotea

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Abstract

High-entropy alloys (HEAs) are a promising class of materials that can grant remarkable functional performances for a large range of applications due to their highly tunable composition. Among these applications, recently, bcc HEAs capable of forming fcc hydrides have been proposed as high-capacity hydrogen storage materials with improved thermodynamics compared to classical metal hydrides. In this context, a single-phase bcc (TiVNb)0.90Cr0.05Mn0.05 HEA was prepared by arc melting to evaluate the effect of combined Cr/Mn addition in the ternary TiVNb. A thermodynamic destabilization of the fcc hydride phase was found in the HEA compared to the initial TiVNb. In situ neutron and synchrotron X-ray diffraction experiments put forward a fcc → bcc phase transition of the metallic subnetwork in the temperature range of 260–350 °C, whereas the H/D subnetwork underwent an order → disorder transition at 180 °C. The absorption/desorption cycling demonstrated very fast absorption kinetics at room temperature in less than 1 min with a remarkable total capacity (2.8 wt.%) without phase segregation. Therefore, the design strategy consisting of small additions of non-hydride-forming elements into refractory HEAs allows for materials with promising properties for solid-state hydrogen storage to be obtained.

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TiVNb 中添加 Cr/Mn 对吸氢特性的影响：热力学和相变研究

高熵合金（HEAs）是一类前景广阔的材料，由于其成分具有高度可调性，因此可以为各种应用提供卓越的功能性能。在这些应用中，最近有人提出，能形成 fcc 水化物的 bcc HEAs 可作为高容量储氢材料，其热力学性能比传统金属水化物更好。在此背景下，通过电弧熔化制备了单相 bcc (TiVNb)0.90Cr0.05Mn0.05 HEA，以评估三元 TiVNb 中联合添加 Cr/Mn 的效果。与初始 TiVNb 相比，在 HEA 中发现 fcc 氢化物相的热力学不稳定性。原位中子和同步辐射 X 射线衍射实验表明，在 260-350 ℃ 的温度范围内，金属子网络发生了 fcc → bcc 相转变，而 H/D 子网络在 180 ℃ 时发生了有序 → 无序转变。在室温下，吸收/解吸循环显示出非常快的吸收动力学，时间不到 1 分钟，总容量（2.8 wt.%）显著提高，且无相位偏析。因此，在难熔 HEA 中少量添加非氢化物形成元素的设计策略可使材料具有固态储氢的良好性能。

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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Hydrogen

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