A brief overview of hydrogen production and storage

Q1 Social Sciences

South African Journal of Chemical Engineering Pub Date : 2025-04-14 DOI:10.1016/j.sajce.2025.04.009

Omotayo Sanni, Xoliswa Dyosiba, Jianwei Ren

{"title":"A brief overview of hydrogen production and storage","authors":"Omotayo Sanni, Xoliswa Dyosiba, Jianwei Ren","doi":"10.1016/j.sajce.2025.04.009","DOIUrl":null,"url":null,"abstract":"<div><div>Given that the demand for hydrogen is predicted to grow by around eight times by 2050 compared to 2020, a number of factors may make it difficult to implement hydrogen applications successfully. Although storing hydrogen is still a major problem, it is seen to be one of the most promising alternative fuels replacing current fossil fuels. Technologies for hydrogen generation have emerged as a key component of the energy mix in a society that seeks to replace fossil fuels in order to reduce greenhouse gas emissions and address other environmental issues. Hydrogen is a clean \"green\" fuel of interest that can help achieve aggressive goals for reducing greenhouse gas emissions between 2035 and 2050. Currently used in industrial application, hydrogen compression and liquefaction are energy-intensive processes because they require low temperature (253 °C) and high pressure (30–70 MPa). Since chemical hydrogen storage allows for the safe storage of hydrogen-rich molecules in ambient settings, it is a possible substitute. Even though there are several molecules that are thought to be hydrogen transporters, some of them lackviable prospects for widespread commercialization. The present status of development of important areas of hydrogen production and storage technologies is reviewed, along with the advantages and disadvantages of each technique in relation to cost, efficiency, safety, and storage capacity. The safety implications of different H<sub>2</sub> storage methods have received particular attention because safety issues are one of the main obstacles to the widespread use of H<sub>2</sub> as a fuel source. This study also identifies the main obstacles and possibilities that the commercialization and development of hydrogen storage technology must overcome, such as the requirement for better materials, better system integration, and greater acceptability and awareness. From the reviewed literature, we have learned that when the challenges and constraints that are involved with the storage and production of hydrogen are adequately addressed, hydrogen will emerge as the first reliable source of energy. Secondly, thorough research on correct hydrogen processing designs will give an indication on the correct costing of these systems thus aiding in the minimization of operational and maintenance expenditures. Lastly, suggestions for further study and advancement with emphasis on bringing these technologies closer to commercial feasibility are reported. Therefore, policymakers, researchers, and scientists could utilize this review as a roadmap to help shape the future of hydrogen.</div></div>","PeriodicalId":21926,"journal":{"name":"South African Journal of Chemical Engineering","volume":"53 ","pages":"Pages 60-72"},"PeriodicalIF":0.0000,"publicationDate":"2025-04-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"South African Journal of Chemical Engineering","FirstCategoryId":"1085","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S1026918525000435","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"Social Sciences","Score":null,"Total":0}

引用次数: 0

Abstract

Given that the demand for hydrogen is predicted to grow by around eight times by 2050 compared to 2020, a number of factors may make it difficult to implement hydrogen applications successfully. Although storing hydrogen is still a major problem, it is seen to be one of the most promising alternative fuels replacing current fossil fuels. Technologies for hydrogen generation have emerged as a key component of the energy mix in a society that seeks to replace fossil fuels in order to reduce greenhouse gas emissions and address other environmental issues. Hydrogen is a clean "green" fuel of interest that can help achieve aggressive goals for reducing greenhouse gas emissions between 2035 and 2050. Currently used in industrial application, hydrogen compression and liquefaction are energy-intensive processes because they require low temperature (253 °C) and high pressure (30–70 MPa). Since chemical hydrogen storage allows for the safe storage of hydrogen-rich molecules in ambient settings, it is a possible substitute. Even though there are several molecules that are thought to be hydrogen transporters, some of them lackviable prospects for widespread commercialization. The present status of development of important areas of hydrogen production and storage technologies is reviewed, along with the advantages and disadvantages of each technique in relation to cost, efficiency, safety, and storage capacity. The safety implications of different H₂ storage methods have received particular attention because safety issues are one of the main obstacles to the widespread use of H₂ as a fuel source. This study also identifies the main obstacles and possibilities that the commercialization and development of hydrogen storage technology must overcome, such as the requirement for better materials, better system integration, and greater acceptability and awareness. From the reviewed literature, we have learned that when the challenges and constraints that are involved with the storage and production of hydrogen are adequately addressed, hydrogen will emerge as the first reliable source of energy. Secondly, thorough research on correct hydrogen processing designs will give an indication on the correct costing of these systems thus aiding in the minimization of operational and maintenance expenditures. Lastly, suggestions for further study and advancement with emphasis on bringing these technologies closer to commercial feasibility are reported. Therefore, policymakers, researchers, and scientists could utilize this review as a roadmap to help shape the future of hydrogen.

查看原文本刊更多论文

氢的生产和储存的简要概述

鉴于到2050年对氢的需求预计将比2020年增长约8倍，许多因素可能使氢的成功应用变得困难。尽管氢的储存仍然是一个主要问题，但它被视为取代目前化石燃料的最有前途的替代燃料之一。在一个寻求取代化石燃料以减少温室气体排放和解决其他环境问题的社会中，制氢技术已成为能源结构的关键组成部分。氢是一种清洁的“绿色”燃料，可以帮助实现2035年至2050年减少温室气体排放的积极目标。目前在工业应用中，氢气压缩和液化是能源密集型的过程，因为它们需要低温（253°C）和高压（30-70 MPa）。由于化学储氢可以在环境环境中安全地储存富氢分子，因此它是一种可能的替代品。尽管有几种分子被认为是氢转运体，但其中一些缺乏广泛商业化的前景。综述了制氢和储氢技术重要领域的发展现状，以及每种技术在成本、效率、安全性和储氢能力方面的优缺点。由于安全问题是H2作为燃料来源广泛使用的主要障碍之一，不同的H2储存方法的安全影响受到了特别的关注。本研究还确定了氢存储技术商业化和发展必须克服的主要障碍和可能性，例如对更好的材料，更好的系统集成以及更高的可接受性和认知度的要求。从回顾的文献中，我们了解到，当氢的储存和生产所涉及的挑战和限制得到充分解决时，氢将成为第一可靠的能源来源。其次，对正确的氢处理设计进行深入研究，将表明这些系统的正确成本，从而有助于将运营和维护支出降至最低。最后，提出了进一步研究和发展的建议，重点是使这些技术更接近商业可行性。因此，政策制定者、研究人员和科学家可以利用这篇综述作为路线图，帮助塑造氢的未来。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

South African Journal of Chemical Engineering Social Sciences-Education

CiteScore

8.40

自引率

0.00%

发文量

100

审稿时长

33 weeks

期刊介绍： The journal has a particular interest in publishing papers on the unique issues facing chemical engineering taking place in countries that are rich in resources but face specific technical and societal challenges, which require detailed knowledge of local conditions to address. Core topic areas are: Environmental process engineering • treatment and handling of waste and pollutants • the abatement of pollution, environmental process control • cleaner technologies • waste minimization • environmental chemical engineering • water treatment Reaction Engineering • modelling and simulation of reactors • transport phenomena within reacting systems • fluidization technology • reactor design Separation technologies • classic separations • novel separations Process and materials synthesis • novel synthesis of materials or processes, including but not limited to nanotechnology, ceramics, etc. Metallurgical process engineering and coal technology • novel developments related to the minerals beneficiation industry • coal technology Chemical engineering education • guides to good practice • novel approaches to learning • education beyond university.