Hydrogen Storage Materials: Room-Temperature Wet-Chemistry Approach toward Mixed-Metal Borohydrides

Jaron Tomasz; Orlowski Piotr A.; Wegner Wojciech; Fijalkowski Karol J.; Leszczynski Piotr J.; Grochala Wojciech

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Hydrogen Storage Materials: Room-Temperature Wet-Chemistry Approach toward Mixed-Metal Borohydrides

机译：储氢材料：室温湿化学方法处理混合金属硼氢化物

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The poor kinetics of hydrogen evolution and the irreversibility of the hydrogen discharge hamper the use of transition metal borohydrides as hydrogen storage materials, and the drawbacks of current synthetic methods obstruct the exploration of these systems. A wet-chemistry approach, which is based on solvent-mediated metathesis reactions of precursors containing bulky organic cations and weakly coordinating anions, leads to mixed-metal borohydrides that contain only a small amount of dead mass. The applicability of this method is exemplified by Li[Zn-2(BH4)(5)] and M[Zn(BH4)(3)] salts (M=Na, K), and its extension to other systems is discussed.

机译：氢放出动力学差以及氢放电的不可逆性妨碍了过渡金属硼氢化物作为储氢材料的使用，并且当前合成方法的缺点阻碍了对这些系统的探索。湿化学方法基于含有大量有机阳离子和弱配位阴离子的前体的溶剂介导的复分解反应，从而导致混合金属硼氢化物仅包含少量的死质量。 Li [Zn-2（BH4）（5）]和M [Zn（BH4）（3）]盐（M = Na，K）举例说明了该方法的适用性，并讨论了其扩展到其他系统的问题。

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《Angewandte Chemie》 |2015年第4期|共4页
作者
Jaron Tomasz; Orlowski Piotr A.; Wegner Wojciech; Fijalkowski Karol J.; Leszczynski Piotr J.; Grochala Wojciech;
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正文语种 eng
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alkali metal halides; borohydrides; hydrogen storage; organic solvents; weakly coordinating anions;

机译：碱金属卤化物;硼氢化物;储氢;有机溶剂;弱配位阴离子;

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1. Hydrogen Storage Materials: Room-Temperature Wet-Chemistry Approach toward Mixed-Metal Borohydrides [J] . Jaron Tomasz, Orlowski Piotr A., Wegner Wojciech, Angewandte Chemie . 2015,第4期

机译：储氢材料：室温湿化学方法处理混合金属硼氢化物
2. Role of Metal Electronegativity in the Dehydrogenation Thermodynamics and Kinetics of Composite Metal Borohydride-LiNH2 Hydrogen Storage Materials [J] . Bai Ying, Pei Ziwei, Wu Feng, ACS applied materials & interfaces . 2018,第11期

机译：金属电阻在复合金属硼氢化物 - LinH2储氢材料中的脱氢热力学和动力学中的作用
3. Complex Ammine Titanium(III) Borohydrides as Advanced Solid Hydrogen-Storage Materials with Favorable Dehydrogenation Properties [J] . Feng Yuan, Qinfen Gu, Xiaowei Chen Chemistry of Materials: A Publication of the American Chemistry Society . 2012,第17期

机译：复杂的氨化硼氢化钛（III）作为先进的具有良好脱氢性能的固体储氢材料
4. Dehydrogenation Thermodynamics of Hydrogen Storage Material Manganese Borohydride: First-Principles Study [C] . Pabitra Choudhury, Venkat R. Bhethanabotla, Elias Stefanakos American Institute of Chemical Engineers Annual Meeting . 2008

机译：储氢锰硼氢化物的脱氢热力学：第一原理研究
5. Development of novel borohydrides as hydrogen storage materials . [D] . Severa, Godwin. 2010

机译：新型硼氢化物作为储氢材料的研究进展。
6. Self-Printing on Graphitic Nanosheets with Metal Borohydride Nanodots for Hydrogen Storage [O] . Yongtao Li, Xiaoli Ding, Qingan Zhang -1

机译：在具有金属硼氢化物纳米点的石墨纳米片上进行自印刷以储氢
7. Mg/Zn mixed-metal borohydride for hydrogen storage:ab initioperiodic computational study of the phase stability and decomposition [O] . B. Civalleri, E. Albanese, E. Pinatel, 2012

机译：用于储氢的Mg / Zn混合金属硼氢化物：AB初始稳定性和分解的初始计算研究
8. Activation and Co-Activation of Molecular Hydrogen and Carbon Monoxide by Transition-Metal and Mixed-Metal Alkoxides and Oxides: A New Approach to Fischer-Tropsch Chemistry. Technical Progress Report, 1 June 1982-31 May 1983 [R] . Chisholm, M. H. 1983

机译：过渡金属和混合金属醇盐和氧化物对分子氢和一氧化碳的活化和共活化：Fischer-Tropsch化学的新方法。技术进步报告，1982年6月1日至1983年5月31日

Hydrogen Storage Materials: Room-Temperature Wet-Chemistry Approach toward Mixed-Metal Borohydrides

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