Development of catalysts for sulfuric acid decomposition in the sulfur–iodine cycle: a review

H. A. Khan, Ahsan Jaleel, Eyas Mahmoud, Shoaib Ahmed, U. H. Bhatti, M. Bilal, Hussain
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引用次数: 5

Abstract

ABSTRACT To achieve carbon-neutral energy vectors, researchers have investigated various sulfur-based thermochemical cycles. The sulfur–iodine cycle has emerged as a cost-effective global process with massive hydrogen production potentials. However, all sulfur-based thermochemical cycles involve sulfuric acid decomposition reaction, which is highly corrosive and energy intensive. The activation energy of this reaction can be reduced using catalysts that decrease the onset temperature of the reaction. Renewable heat sources such as solar and waste nuclear heat demand high stability to operate within a wide temperature window (650°C–900°C). Several metal/metal oxide systems based on noble and transition metals have been investigated over the last twenty years. In the literature, supported Pt-based catalysts are regarded as the prime choice for stable operations. However, during catalytic operations, noble metals are degraded owing to sintering, oxidation, leaching, and other processes. Transition metal oxides such as Fe, Cu, Cr, and Ni exhibit promising catalytic activity at high temperatures; however, at low temperatures (>600°C), their activation is reduced owing to poisoning and the formation of stable sulfate species. The catalytic activity of transition metal oxides is determined by the decomposition temperature of its corresponding metal sulfate; thus, the metal sulfate formation is considered as the rate-limiting step. Herein, the catalytic systems studied over the last decade are summarized, and recommendations for designing robust catalysts for commercial applications are presented.
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硫碘循环中硫酸分解催化剂的研究进展
为了实现碳中和的能量载体,研究人员研究了各种基于硫的热化学循环。硫碘循环已成为具有巨大制氢潜力的具有成本效益的全球工艺。然而,所有基于硫的热化学循环都涉及硫酸分解反应,这是一个高腐蚀性和能源密集型的反应。使用降低反应起始温度的催化剂可以降低该反应的活化能。可再生热源,如太阳能和废核热,需要在宽温度窗(650°C - 900°C)内运行的高稳定性。在过去的二十年里,人们研究了几种基于贵金属和过渡金属的金属/金属氧化物体系。在文献中,负载pt基催化剂被认为是稳定操作的首选。然而,在催化操作过程中,贵金属由于烧结、氧化、浸出和其他过程而被降解。过渡金属氧化物如Fe、Cu、Cr和Ni在高温下表现出良好的催化活性;然而,在低温(>600°C)下,由于中毒和形成稳定的硫酸盐物质,它们的活性降低。过渡金属氧化物的催化活性由其对应的金属硫酸盐的分解温度决定;因此,金属硫酸盐的形成被认为是限速步骤。本文对近十年来研究的催化体系进行了总结,并提出了设计用于商业应用的稳健催化剂的建议。
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