H2 as Clean Energy for Sustainable Future

Universal Journal of Catalysis Science Pub Date : 2023-09-22 DOI:10.37256/ujcs.1220232208

Sovann Khan, Veasna Soum

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Abstract

H2 is considered a clean fuel used in Fuel cell technology for electricity generation with zero greenhouse gas (GHG) emission. The demand for H2 gas, typically for fuel cell electric vehicles (FCEVs), is increasing. However, the current H2 production relies on natural gas and coals related to carbon oxide gas emission, which gives back to global warming concerns. Low-carbon production processes are needed to contribute to the United Nation's sustainable development goals (SDGs). Water-splitting reaction using photocatalysis or electrocatalysis is a promising method for producing H2 from water, which is the earthabundant resource. These H2 production methods based on catalytic technologies require highly active catalyst materials with long-term stability. The development of non-conventional materials with consideration of nanostructure, multijunction, and defect engineering is explored to achieve highly active catalyst materials. This mini-review discusses a basic understanding of H2 production from water-splitting reactions via photocatalysis and electrocatalysis, with outstanding examples of recent works reported. Last part, we provide a short study on the H2 global market and policy in order to conclude the future direction of H2 energy.

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氢气是未来可持续发展的清洁能源

氢气被认为是用于零温室气体(GHG)排放发电的燃料电池技术中的清洁燃料。燃料电池电动汽车(fcev)对氢气的需求正在增加。然而，目前的氢气生产依赖于与二氧化碳气体排放相关的天然气和煤炭，这又引起了全球变暖的担忧。低碳生产过程需要为联合国的可持续发展目标(sdg)做出贡献。水是地球上资源丰富的资源，光催化或电催化水解反应是一种很有前途的制氢方法。这些基于催化技术的制氢方法需要具有长期稳定性的高活性催化剂材料。从纳米结构、多结和缺陷工程等方面探索非常规材料的发展，以实现高活性催化剂材料。这篇综述讨论了通过光催化和电催化从水裂解反应中产生氢气的基本认识，并介绍了最近报道的一些杰出的研究成果。最后，我们对全球氢气市场和政策进行了简要的研究，以总结氢气能源的未来发展方向。

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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Universal Journal of Catalysis Science

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