The mechanochemistry of lanthanum dihydride (LaH\(_{2}\)) with hydrogen (H\(_{2}\)) using the ball-mill process and the effect of oxidation on the resulting products

IF 0.7 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of metals, materials and minerals Pub Date : 2024-06-04 DOI:10.55713/jmmm.v34i2.1825

A. Pramono, Satrio Herbirowo, A. Imaduddin, Iwan Dwi Antoro, H. Nugraha, Hendrik, Anung Syampurwadi, Ines Hayatun Nufus, Nihayatul Umna, Silvia Farah Diba, Fina Fitratun Amaliyah

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Abstract

The complex behavior of LaH2 during ball milling was investigated in this study, with its mechanical, chemical, and morphological changes explored. The relationship between milling time and hydrogen pressure reduction was uncovered through detailed experiments, reflecting the dynamic nature of the process. A transient yet significant event was observed upon unsealing the milling jar post-milling: the emergence of a minor fire ember, indicative of the interplay between mechanical forces and chemical reactivity within the LaH2 powder. Profound changes in the structure, composition, and shape were unraveled using advanced techniques such as X-ray diffraction (XRD), scanning electron microscopy coupled with energy-dispersive X-ray spectroscopy (SEM/EDX), and particle size distribution analysis. The resulting powder exhibited a dual-phase composition of lanthanum dihydride (LaH2, 68.1% to 71.5%) and lanthanum oxide (La2O3, 28.5% to 31.9%), reflecting a dynamic chemical equilibrium during milling. Particle size distribution analysis revealed a notable increase in average diameter to 6420 nm, accompanied by a polydispersity index (PDI) of 0.831, signifying a broadening compared to the initial LaH2 powder. The morphological evolution of the powder was elucidated through SEM imaging, showing predominantly spherical and rounded forms, indicating extensive particle agglomeration and plastic deformation during milling. Additionally, the formation of oxide layers on the powder surface, intertwined with pronounced particle agglomeration, was highlighted through EDX mapping, shedding light on the mechanical aspects of morphological evolution during milling. These findings contribute to our understanding of LaH2 behavior under extreme mechanical and chemical conditions and have implications for materials processing, hydrogen storage technologies, and broader applications in materials science and engineering.

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利用球磨工艺将二氢化镧（LaH\(_{2}\)）与氢（H\(_{2}\)）进行机械化学反应以及氧化作用对生成物的影响

本研究调查了 LaH2 在球磨过程中的复杂行为，探讨了其机械、化学和形态变化。通过详细的实验揭示了研磨时间与氢压降低之间的关系，反映了这一过程的动态性质。在研磨后打开密封罐时，观察到了一个瞬时而重要的事件：出现了一个小火苗，这表明了 LaH2 粉末中机械力和化学反应性之间的相互作用。利用 X 射线衍射 (XRD)、扫描电子显微镜结合能量色散 X 射线光谱 (SEM/EDX) 和粒度分布分析等先进技术，揭示了结构、成分和形状的深刻变化。得到的粉末呈现出二氢化镧（LaH2，68.1%-71.5%）和氧化镧（La2O3，28.5%-31.9%）的双相组成，反映了研磨过程中的动态化学平衡。粒度分布分析表明，平均直径明显增加到 6420 纳米，多分散指数 (PDI) 为 0.831，表明与最初的 LaH2 粉末相比，粒度有所扩大。粉末的形态演变通过扫描电子显微镜成像得以阐明，主要呈球形和圆形，表明研磨过程中出现了广泛的颗粒团聚和塑性变形。此外，EDX 图谱还突出显示了粉末表面氧化层的形成与明显的颗粒团聚交织在一起，从而揭示了研磨过程中形态演变的力学方面。这些发现有助于我们了解 LaH2 在极端机械和化学条件下的行为，对材料加工、储氢技术以及材料科学和工程学的更广泛应用具有重要意义。

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来源期刊

Journal of metals, materials and minerals MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

1.40

自引率

11.10%

发文量

期刊介绍： Journal of Metals, Materials and Minerals (JMMM) is a double-blind peer-reviewed international journal published 4 issues per year (starting from 2019), in March, June, September, and December, aims at disseminating advanced knowledge in the fields to academia, professionals and industrialists. JMMM publishes original research articles as well as review articles related to research and development in science, technology and engineering of metals, materials and minerals, including composite & hybrid materials, concrete and cement-based systems, ceramics, glass, refractory, semiconductors, polymeric & polymer-based materials, conventional & technical textiles, nanomaterials, thin films, biomaterials, and functional materials.