Synthesis of Ni-B/Hydroxyapatite by Electrochemical Method and Its Application as Catalyst on NaBH4 Hydrolysis

Journal of Metastable and Nanocrystalline Materials Pub Date : 2021-06-15 DOI:10.4028/www.scientific.net/JMNM.33.29

A. Nur, N. Nazriati, F. Fajaroh, A. Arthaningrum, I. Nurcahyani, D. L. Cipto, F. Kurniawan

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Abstract

The result of burning hydrogen which is environmentally friendly makes hydrogen as a very attractive fuel. Hydrogen storage is interesting research material. One alternative to hydrogen storage is a metal-hydride as NaBH4. In this paper, the catalyst for hydrogen production from storage, namely The result of burning hydrogen, which is environmentally friendly, makes hydrogen a desirable fuel. Hydrogen storage is exciting research material. One alternative to hydrogen storage is a metal-hydride as NaBH4. In this paper, the catalyst for hydrogen production from storage, namely NaBH4, was synthesized by electrochemical. Ni-B catalyst with hydroxyapatite as catalyst support was prepared by electrochemical. Ni-B/HA catalyst was synthesized at various current densities (namely 67, 133, and 200 mA/cm2) and various electrolysis times (namely 30, 60, and 90 minutes). The resulting catalysts were analyzed by XRD and used as the catalyst for hydrogen production from the hydrolysis reaction of NaBH4. The fastest hydrogen production was obtained using a catalyst generated at 133 mA/cm2 and an electrolysis time of 60 minutes. The reaction rate equation for the hydrolysis of NaBH4 has a first-order reaction to the concentration of NaBH4. The resulting reaction rate constant ranged from 233.33 mL/g/min to 861.11 mL/g/min. The relationship between reaction temperature and reaction rate constant can be expressed by the equation k = 2.2x106exp (5534/T).

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电化学法合成Ni-B/羟基磷灰石及其在NaBH4水解催化剂中的应用

燃烧氢气的结果是环保的，使氢气成为一种非常有吸引力的燃料。储氢是一种有趣的研究材料。氢储存的一种替代品是金属氢化物NaBH4。在本文中，从储存制氢的催化剂，即燃烧氢的结果，是环保的，使氢成为理想的燃料。氢储存是令人兴奋的研究材料。氢储存的一种替代品是金属氢化物NaBH4。本文采用电化学方法合成了储氢制氢催化剂NaBH4。以羟基磷灰石为催化剂载体，采用电化学方法制备了Ni-B催化剂。在不同电流密度(67、133和200 mA/cm2)和不同电解时间(30、60和90分钟)下合成Ni-B/HA催化剂。采用XRD对所得催化剂进行了分析，并将其作为NaBH4水解制氢的催化剂。在电解时间为60分钟的条件下，催化剂的产氢速率为133 mA/cm2，产氢速度最快。NaBH4的水解反应速率方程与NaBH4的浓度呈一级反应。反应速率常数为233.33 mL/g/min ~ 861.11 mL/g/min。反应温度与反应速率常数的关系式为k = 2.2x106exp (5534/T)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Metastable and Nanocrystalline Materials

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