A Techno-Economic Study of Photovoltaic-Solid Oxide Electrolysis Cells Coupled Magnesium Hydrides-based Hydrogen Storage and Transportation Toward Large-Scale Applications of Green Hydrogen
Xusheng Wang, Longfei Shao, Shouyi Hu, Zi Li, Hangzuo Guo, Jiaqi Zhang, Yingyan Zhao, Xi Lin, Binjian Nie, Zhigang Hu, Jianxin Zou
{"title":"A Techno-Economic Study of Photovoltaic-Solid Oxide Electrolysis Cells Coupled Magnesium Hydrides-based Hydrogen Storage and Transportation Toward Large-Scale Applications of Green Hydrogen","authors":"Xusheng Wang, Longfei Shao, Shouyi Hu, Zi Li, Hangzuo Guo, Jiaqi Zhang, Yingyan Zhao, Xi Lin, Binjian Nie, Zhigang Hu, Jianxin Zou","doi":"10.1039/d4ee04224g","DOIUrl":null,"url":null,"abstract":"The large-scale development of green hydrogen energy offers a critical solution to the challenges posed by greenhouse gas (GHG) emissions and global climate change. Conducting an early technical and economic evaluation of an efficient and safe hydrogen production, storage, and transportation pathway is challenging but essential for enhancing the future global hydrogen energy supply chain. In this work, we conceive and forward a new hydrogen utilization route via photovoltaic-solid oxide electrolysis cells coupled with magnesium hydrides-based hydrogen storage and transportation (PV-SOEC-MgH2). The detailed design and simulation suggests that the thermal integration between SOEC and hydrogenation processes of magnesium exerts the energy and exergy efficiencies of 86.71% and 42.31%, respectively, in the hydrogen production process. The optimization of the fins and transfer structures in the metal hydride bed exerts the potential to increase the SOEC electrical efficiency by 5-9.3%. Besides, by implementing engineering operation data from solid oxide electrolysis cells (SOECs) and magnesium hydrides-based hydrogen storage and transportation technology, we evaluate the technological feasibility, economic viability, thermodynamic performance, and environmental impact of this hydrogen utilization route and investigates its large-scale application potential. The current levelized cost of hydrogen (LCOH) production by PV-SOEC in China is estimated to range from 3.3 $ kgH2-1 to 5.8 $ kgH2-1, and will be minimized to 1.20-1.73 $ kgH2-1 by 2050 along with the technology development. In addition, the LCOH in production is projected to decrease to 1.52 $ kgH2-1 and 1.64 $ kgH2-1 in solar-rich regions in Australia and the United States by 2050, respectively. Furthermore, the hydrogen cost is primarily influenced by regional factors and specific application scenarios, and the minimum production, delivery, and supply cost of hydrogen for refuelling cars in Shanghai is 7.68 $ kgH2-1, which might be potentially lowered to 5.68 $ kgH2-1 by 2030 and 4.08 $ kgH2-1 by 2050. Our findings offer both technological and economic insights into the global large-scale hydrogen energy applications in the future based on this new PV-SOEC-MgH2 technical route.","PeriodicalId":72,"journal":{"name":"Energy & Environmental Science","volume":null,"pages":null},"PeriodicalIF":32.4000,"publicationDate":"2024-10-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Energy & Environmental Science","FirstCategoryId":"88","ListUrlMain":"https://doi.org/10.1039/d4ee04224g","RegionNum":1,"RegionCategory":"材料科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"CHEMISTRY, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 0
Abstract
The large-scale development of green hydrogen energy offers a critical solution to the challenges posed by greenhouse gas (GHG) emissions and global climate change. Conducting an early technical and economic evaluation of an efficient and safe hydrogen production, storage, and transportation pathway is challenging but essential for enhancing the future global hydrogen energy supply chain. In this work, we conceive and forward a new hydrogen utilization route via photovoltaic-solid oxide electrolysis cells coupled with magnesium hydrides-based hydrogen storage and transportation (PV-SOEC-MgH2). The detailed design and simulation suggests that the thermal integration between SOEC and hydrogenation processes of magnesium exerts the energy and exergy efficiencies of 86.71% and 42.31%, respectively, in the hydrogen production process. The optimization of the fins and transfer structures in the metal hydride bed exerts the potential to increase the SOEC electrical efficiency by 5-9.3%. Besides, by implementing engineering operation data from solid oxide electrolysis cells (SOECs) and magnesium hydrides-based hydrogen storage and transportation technology, we evaluate the technological feasibility, economic viability, thermodynamic performance, and environmental impact of this hydrogen utilization route and investigates its large-scale application potential. The current levelized cost of hydrogen (LCOH) production by PV-SOEC in China is estimated to range from 3.3 $ kgH2-1 to 5.8 $ kgH2-1, and will be minimized to 1.20-1.73 $ kgH2-1 by 2050 along with the technology development. In addition, the LCOH in production is projected to decrease to 1.52 $ kgH2-1 and 1.64 $ kgH2-1 in solar-rich regions in Australia and the United States by 2050, respectively. Furthermore, the hydrogen cost is primarily influenced by regional factors and specific application scenarios, and the minimum production, delivery, and supply cost of hydrogen for refuelling cars in Shanghai is 7.68 $ kgH2-1, which might be potentially lowered to 5.68 $ kgH2-1 by 2030 and 4.08 $ kgH2-1 by 2050. Our findings offer both technological and economic insights into the global large-scale hydrogen energy applications in the future based on this new PV-SOEC-MgH2 technical route.
期刊介绍:
Energy & Environmental Science, a peer-reviewed scientific journal, publishes original research and review articles covering interdisciplinary topics in the (bio)chemical and (bio)physical sciences, as well as chemical engineering disciplines. Published monthly by the Royal Society of Chemistry (RSC), a not-for-profit publisher, Energy & Environmental Science is recognized as a leading journal. It boasts an impressive impact factor of 8.500 as of 2009, ranking 8th among 140 journals in the category "Chemistry, Multidisciplinary," second among 71 journals in "Energy & Fuels," second among 128 journals in "Engineering, Chemical," and first among 181 scientific journals in "Environmental Sciences."
Energy & Environmental Science publishes various types of articles, including Research Papers (original scientific work), Review Articles, Perspectives, and Minireviews (feature review-type articles of broad interest), Communications (original scientific work of an urgent nature), Opinions (personal, often speculative viewpoints or hypotheses on current topics), and Analysis Articles (in-depth examination of energy-related issues).