(Ni–TiO2)@C-catalyzed hydrogen storage performance of a Mg–Ni–Y alloy with LPSO and ternary eutectic structure

IF 5 3区材料科学 Q2 CHEMISTRY, PHYSICAL

Sustainable Energy & Fuels Pub Date : 2024-12-16 DOI:10.1039/D4SE01346H

Wenjie Song, Yili Gou, Wenhao Ma, Wei Chen, Yazhen Li, Yuzhi Li, Huijin Jin and Yuejin Yuan

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Abstract

A Mg₉₃Ni_3.5Y_3.5 hydrogen storage alloy was prepared using a composition design approach with a protective covering agent method. A self-synthesized 1 wt% nano (Ni–TiO₂)@C catalyst was added by ball milling. The in situ formation of the endogenous long-period stacking ordered (LPSO) phase facilitated the catalytic decomposition of products after hydrogenation. The synergistic effect of the external and in situ endogenous catalysts enhanced the hydrogen absorption and desorption capacities, increased the reaction rate and lowered the temperature corresponding to the maximum hydrogen storage capacity. The composite material absorbed up to 6.39 wt% of hydrogen at 300 °C and 30 bar. Even at 100 °C, it absorbed 3.87 wt% of hydrogen within 2 hours. The enthalpies of formation for the materials Mg₉₃Ni_3.5Y_3.5 and Mg₉₃Ni_3.5Y_3.5 + (Ni–TiO₂)@C (with the added catalyst) were −53.96 and −55.04 kJ mol⁻¹ H₂, respectively. The corresponding hydrogen absorption activation energies were −34.14 and −39.51 kJ mol⁻¹ H₂. In addition, the material displayed excellent cycling stability after 100 cycles with the addition of the catalyst.

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（Ni-TiO2）@ c催化具有LPSO和三元共晶结构的Mg-Ni-Y合金的储氢性能

采用保护剂法制备了Mg93Ni3.5Y3.5储氢合金。采用球磨法添加了自合成的1 wt%纳米（Ni-TiO2）@C催化剂。内源性长周期有序堆积相（LPSO）的原位形成促进了加氢后产物的催化分解。外源催化剂和原位内源催化剂的协同作用增强了氢的吸附和解吸能力，提高了反应速率，降低了最大储氢容量对应的温度。该复合材料在300℃和30 bar条件下可吸收高达6.39 wt%的氢。即使在100℃下，它在2小时内也能吸收3.87 wt%的氢。在添加催化剂的情况下，Mg93Ni3.5Y3.5和Mg93Ni3.5Y3.5 + (Ni-TiO2)@C的生成焓分别为−53.96和−55.04 kJ mol−1 H2。相应的氢吸收活化能分别为−34.14和−39.51 kJ mol−1 H2。此外，添加催化剂后，材料在100次循环后表现出优异的循环稳定性。

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来源期刊

Sustainable Energy & Fuels Energy-Energy Engineering and Power Technology

CiteScore

10.00

自引率

3.60%

发文量

394

期刊介绍： Sustainable Energy & Fuels will publish research that contributes to the development of sustainable energy technologies with a particular emphasis on new and next-generation technologies.