海水电解催化剂综述

Jihong Li , Genyuan Fu , Xiaokun Sheng , Guodong Li , Hui Chen , Kaiqian Shu , Yan Dong , Tongzhou Wang , Yida Deng
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引用次数: 0

摘要

海水电解是一种可持续的能源转换技术,通过将海水分离成氢气和氧气来产生清洁能源。然而,由于海水中存在高浓度的盐离子和其他杂质,海水电解中使用的催化剂往往面临着巨大的稳定性挑战。本综述旨在分析影响海水电解催化剂稳定性的关键因素,阐明腐蚀和电化学降解机制,并深入探讨提高催化剂稳定性的各种策略。这些策略包括催化剂材料选择、表面改性技术、催化剂支撑材料和催化剂设计策略。通过深入了解有关海水电解催化剂稳定性的障碍和创新,本综述力图加快这一技术的商业化进程,并将其作为一种可再生的可行制氢方法广泛采用。最终,我们的目标是通过从海水中高效、持久地制氢,创造一个更清洁、更可持续的未来。
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A comprehensive review on catalysts for seawater electrolysis

Seawater electrolysis is a sustainable energy conversion technology that generates clean energy by splitting seawater into hydrogen and oxygen. However, the catalysts used in seawater electrolysis often face significant stability challenges because of the high concentration of salt ions and other impurities present in seawater. This review aims to discern the pivotal factors influencing catalyst stability in seawater electrolysis, elucidate the corrosion and electrochemical degradation mechanisms, and delve into the various strategies employed to enhance catalyst stability. These strategies encompass catalyst material selection, surface modification techniques, catalyst support materials, and catalyst design strategies. By gaining deeper insights into the obstacles and innovations concerning catalyst stability in seawater electrolysis, this review strives to expedite progress toward the commercialization and widespread adoption of this technology as a renewable and feasible approach for hydrogen production. Ultimately, the goal is to foster a cleaner and more sustainable future by enabling the efficient and enduring generation of hydrogen from seawater.

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