Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach

Hydrogen (H2) is a possible energy transporter and feedstock for energy decarbonization, transportation, and chemical sectors while reducing global warming's consequences. The predominant commercial method for producing H2 today is steam methane reforming (SMR). However, there is still room for...

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Main Authors: Qureshi, F., Yusuf, M., Ibrahim, H., Kamyab, H., Chelliapan, S., Pham, C.Q., Vo, D.-V.N.
Format: Article
Published: Academic Press Inc. 2023
Online Access:http://scholars.utp.edu.my/id/eprint/37483/
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85154585869&doi=10.1016%2fj.envres.2023.115963&partnerID=40&md5=4e4a3c501fb48fc067a173eae29d1489
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spelling oai:scholars.utp.edu.my:374832023-10-04T13:19:16Z http://scholars.utp.edu.my/id/eprint/37483/ Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach Qureshi, F. Yusuf, M. Ibrahim, H. Kamyab, H. Chelliapan, S. Pham, C.Q. Vo, D.-V.N. Hydrogen (H2) is a possible energy transporter and feedstock for energy decarbonization, transportation, and chemical sectors while reducing global warming's consequences. The predominant commercial method for producing H2 today is steam methane reforming (SMR). However, there is still room for development in process intensification, energy optimization, and environmental concerns related to CO2 emissions. Reactors using metallic membranes (MRs) can handle both problems. Compared to traditional reactors, MRs operates at substantially lower pressures and temperatures. As a result, capital and operational costs may be significantly cheaper than traditional reactors. Furthermore, metallic membranes (MMs), particularly Pd and its alloys, naturally permit only H2 permeability, enabling the production of a stream with a purity of up to 99.999. This review describes several methods for H2 production based on the energy sources utilized. SRM with CO2 capture and storage (CCUS), pyrolysis of methane, and water electrolysis are all investigated as process technologies. A debate based on a color code was also created to classify the purity of H2 generation. Although producing H2 using fossil fuels is presently the least expensive method, green H2 generation has the potential to become an affordable alternative in the future. From 2030 onward, green H2 is anticipated to be less costly than blue hydrogen. Green H2 is more expensive than fossil-based H2 since it uses more energy. Blue H2 has several tempting qualities, but the CCUS technology is pricey, and blue H2 contains carbon. At this time, almost 80�95 of CO2 can be stored and captured by the CCUS technology. Nanomaterials are becoming more significant in solving problems with H2 generation and storage. Sustainable nanoparticles, such as photocatalysts and bio-derived particles, have been emphasized for H2 synthesis. New directions in H2 synthesis and nanomaterials for H2 storage have also been discussed. Further, an overview of the H2 value chain is provided at the end, emphasizing the financial implications and outlook for 2050, i.e., carbon-free H2 and zero-emission H2. © 2023 Elsevier Inc. Academic Press Inc. 2023 Article NonPeerReviewed Qureshi, F. and Yusuf, M. and Ibrahim, H. and Kamyab, H. and Chelliapan, S. and Pham, C.Q. and Vo, D.-V.N. (2023) Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach. Environmental Research, 229. ISSN 00139351 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85154585869&doi=10.1016%2fj.envres.2023.115963&partnerID=40&md5=4e4a3c501fb48fc067a173eae29d1489 10.1016/j.envres.2023.115963 10.1016/j.envres.2023.115963 10.1016/j.envres.2023.115963
institution Universiti Teknologi Petronas
building UTP Resource Centre
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Petronas
content_source UTP Institutional Repository
url_provider http://eprints.utp.edu.my/
description Hydrogen (H2) is a possible energy transporter and feedstock for energy decarbonization, transportation, and chemical sectors while reducing global warming's consequences. The predominant commercial method for producing H2 today is steam methane reforming (SMR). However, there is still room for development in process intensification, energy optimization, and environmental concerns related to CO2 emissions. Reactors using metallic membranes (MRs) can handle both problems. Compared to traditional reactors, MRs operates at substantially lower pressures and temperatures. As a result, capital and operational costs may be significantly cheaper than traditional reactors. Furthermore, metallic membranes (MMs), particularly Pd and its alloys, naturally permit only H2 permeability, enabling the production of a stream with a purity of up to 99.999. This review describes several methods for H2 production based on the energy sources utilized. SRM with CO2 capture and storage (CCUS), pyrolysis of methane, and water electrolysis are all investigated as process technologies. A debate based on a color code was also created to classify the purity of H2 generation. Although producing H2 using fossil fuels is presently the least expensive method, green H2 generation has the potential to become an affordable alternative in the future. From 2030 onward, green H2 is anticipated to be less costly than blue hydrogen. Green H2 is more expensive than fossil-based H2 since it uses more energy. Blue H2 has several tempting qualities, but the CCUS technology is pricey, and blue H2 contains carbon. At this time, almost 80�95 of CO2 can be stored and captured by the CCUS technology. Nanomaterials are becoming more significant in solving problems with H2 generation and storage. Sustainable nanoparticles, such as photocatalysts and bio-derived particles, have been emphasized for H2 synthesis. New directions in H2 synthesis and nanomaterials for H2 storage have also been discussed. Further, an overview of the H2 value chain is provided at the end, emphasizing the financial implications and outlook for 2050, i.e., carbon-free H2 and zero-emission H2. © 2023 Elsevier Inc.
format Article
author Qureshi, F.
Yusuf, M.
Ibrahim, H.
Kamyab, H.
Chelliapan, S.
Pham, C.Q.
Vo, D.-V.N.
spellingShingle Qureshi, F.
Yusuf, M.
Ibrahim, H.
Kamyab, H.
Chelliapan, S.
Pham, C.Q.
Vo, D.-V.N.
Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach
author_facet Qureshi, F.
Yusuf, M.
Ibrahim, H.
Kamyab, H.
Chelliapan, S.
Pham, C.Q.
Vo, D.-V.N.
author_sort Qureshi, F.
title Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach
title_short Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach
title_full Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach
title_fullStr Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach
title_full_unstemmed Contemporary avenues of the Hydrogen industry: Opportunities and challenges in the eco-friendly approach
title_sort contemporary avenues of the hydrogen industry: opportunities and challenges in the eco-friendly approach
publisher Academic Press Inc.
publishDate 2023
url http://scholars.utp.edu.my/id/eprint/37483/
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85154585869&doi=10.1016%2fj.envres.2023.115963&partnerID=40&md5=4e4a3c501fb48fc067a173eae29d1489
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