用于储氢的氢化物形成材料的动力学行为

J. Puszkiel
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引用次数: 13

摘要

氢化物形成材料,即二元、复合氢化物及其混合物,由于其潜在的储氢性能而得到了广泛的研究。它们具有较高的体积氢容量和相对较高的重量氢容量。然而,制约其实际应用的主要因素之一是其缓慢的动力学行为。因此,人们一直在努力提高加氢和脱氢速率。目前已经开发了几种策略来增强最相关的氢化物形成材料的动力学行为,如MgH2, MBH4 (M = Li, Ca, Mg, Na, K), MNH2 (M = Li和Mg), MBH4 + ' MH2 (M = Li, Ca, Mg;' M = Li, Mg, Ca)和MNH2 + ' MH2 (M = Li, Mg;M = Li)。调整这些氢化物形成材料的动力学行为涉及不同的方法和它们的组合。最相关的方法是:(1)通过机械铣削提高微观结构的细化,(2)掺杂过渡金属和过渡金属化合物,(3)形成原位催化剂,(4)纳米限制掺杂氢化物形成材料。本文对氢化物形成/分解化学反应的基本概念、热力学、动力学以及提高氢化物和体系动力学行为的应用策略进行了全面的阐述和讨论。
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Tailoring the Kinetic Behavior of Hydride Forming Materials for Hydrogen Storage
Hydride forming materials, i.e., binary, complex hydrides, and their mixtures, have been extensively investigated owing to their potential hydrogen storage properties. They possess high volumetric hydrogen capacity and relative high gravimetric hydrogen capacity. However, one of the main constraints for their practical application is their slow kinetic behavior. For this reason, enormous effort has been devoted to improve the hydrogenation and dehydrogenation rates. Several strategies have been developed for the enhancement of the kinetic behavior of the most relevant hydride forming materials such as MgH2, MBH4 (M = Li, Ca, Mg, Na, K), MNH2 (M = Li and Mg), MBH4 + ‘MH2 (M = Li, Ca, Mg; ‘M = Li, Mg, Ca), and MNH2 + ‘MH2 (M = Li, Mg; ‘M = Li). Tuning the kinetic behavior of these hydride forming materials involves different approaches and their combinations. The most relevant approaches are: (1) improving the microstructural refinement via mechanical milling, (2) doping with transition metal and transition metal compounds, (3) forming in situ catalyst, and (4) nanoconfining doped hydride forming materials. Herein, basic concepts about the chemical reaction for the hydride compound formation/decomposition, thermodynamics, kinetics, and applied strategies to enhance the kinetic behavior of hydride compounds and systems are comprehensively described and discussed.
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2 Behaviors of gold nanoparticles Index 1 Synthesis of gold nanostructures Frontmatter 3 Gold applied to nanomedicine
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