一种有前途的固态储氢方法:高压扭挤压机械纳米结构合成镁

IF 1 Q3 ENGINEERING, MULTIDISCIPLINARY Advances in Science and Technology-Research Journal Pub Date : 2023-11-10 DOI:10.4028/p-4ccboq
Babak Omranpour Shahreza, Fjodor Sergejev, Julia Ivanisenko, Jacques Huot
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引用次数: 0

摘要

本文以纯镁为研究对象,研究了高压扭转挤压(HPTE)对镁合金显微组织、硬度和储氢量的影响。HPTE是一种现代机械纳米结构技术,它可以细化材料的微观结构性能,从而影响材料的力学和功能性能。本研究中使用了两种HPTE方案:(1)无旋转直接挤出(DE),(2)挤出速度为6 mm/min,转速为1.8 rpm (v6w1.8)。在收到的条件下,还测试了一个样品作为参考。结果表明,经过HPTE处理后,材料的硬度有所提高,DE样品硬度达到60 HRB, v6w1.8样品硬度呈71 ~ 83 HRB的梯度分布。x射线衍射分析显示v6w1.8样品的显微组织有明显的细化。氢化动力学结果表明,DE样品的氢吸收率高达1.2 wt.%,而v6w1.8样品的氢吸收率为7.2 wt.%,接近镁的理论储氢量(7.6 wt.%)。这些发现突出了HPTE在微观结构细化和氢储存方面的积极作用,展示了它在材料科学和氢基能源技术方面的进步潜力。
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A Promising Approach to Solid-State Hydrogen Storage: Mechanical Nanostructuring Synthesis of Magnesium by High Pressure Torsion Extrusion
This article presents an investigation into the impact of High Pressure Torsion Extrusion (HPTE) on the microstructural features, hardness and hydrogen storage, focusing on pure magnesium. HPTE is a modern mechanical nanostructuring technique that can refine the microstructural properties and subsequently affects the mechanical and functional properties of the materials. Two HPTE regimes were used in this study: (1) Direct Extrusion without rotation (DE), and (2) an extrusion speed of 6 mm/min along with a rotational speed of 1.8 rpm (v6w1.8). One sample in as-received conditions was also tested as a reference. Results showed increased hardness in the material after HPTE processing, with the DE sample reaching 60 HRB and the v6w1.8 sample exhibiting a gradient distribution of hardness from 71 to 83 HRB. X-ray diffraction analysis revealed significant microstructural refinement in the v6w1.8 sample. Results of hydrogenation kinetics showed that the DE sample absorbed up to 1.2 wt.% of hydrogen, while the v6w1.8 sample displayed 7.2 wt.% of hydrogen absorption, approaching the theoretical hydrogen storage capacity for magnesium (7.6 wt.%). These findings highlight the positive effects of HPTE on microstructural refinement and hydrogen storage, showcasing its potential for advancements in materials science and hydrogen-based energy technologies.
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来源期刊
Advances in Science and Technology-Research Journal
Advances in Science and Technology-Research Journal ENGINEERING, MULTIDISCIPLINARY-
CiteScore
1.60
自引率
27.30%
发文量
152
审稿时长
8 weeks
期刊最新文献
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