Hydrogen Production Technologies: From Fossil Fuels toward Renewable Sources. A Mini Review

Energy & Fuels, Journal Year: 2021, Volume and Issue: 35(20), P. 16403 - 16415

Published: Oct. 7, 2021

The global economic growth, the increase in population, and advances technology lead to an increment primary energy demand. Considering that most of this is currently supplied by fossil fuels, a considerable amount greenhouse gases are emitted, contributing climate change, which reason why next European Union binding agreement focused on reducing carbon emissions using hydrogen. This study reviews different technologies for hydrogen production renewable non-renewable resources. Furthermore, comparative analysis performed renewable-based evaluate economically energetically more promising. results show how biomass-based allow similar yield compared those obtained with water-based but higher efficiencies lower operational costs. More specifically, biomass gasification steam reforming proper balance between studied parameters, being technique allows yields, while energy-efficient. Nevertheless, application as vector future requires both use feedstocks sustainable source. combination would potentially produce green dioxide emissions, limiting and, thus, achieving so-called economy.

Language: Английский

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Biorenewable hydrogen production through biomass gasification: A review and future prospects

Environmental Research, Journal Year: 2020, Volume and Issue: 186, P. 109547 - 109547

Published: April 18, 2020

Language: Английский

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The future of hydrogen energy: Bio-hydrogen production technology

International Journal of Hydrogen Energy, Journal Year: 2022, Volume and Issue: 47(79), P. 33677 - 33698

Published: Sept. 1, 2022

Language: Английский

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Is the H2 economy realizable in the foreseeable future? Part I: H2 production methods

International Journal of Hydrogen Energy, Journal Year: 2020, Volume and Issue: 45(27), P. 13777 - 13788

Published: April 2, 2020

Language: Английский

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A comprehensive review of the promising clean energy carrier: Hydrogen production, transportation, storage, and utilization (HPTSU) technologies

Fuel, Journal Year: 2023, Volume and Issue: 355, P. 129455 - 129455

Published: Aug. 16, 2023

Language: Английский

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A Critical Review of Renewable Hydrogen Production Methods: Factors Affecting Their Scale-Up and Its Role in Future Energy Generation

Membranes, Journal Year: 2022, Volume and Issue: 12(2), P. 173 - 173

Published: Feb. 1, 2022

An increase in human activities and population growth have significantly increased the world's energy demands. The major source of for world today is from fossil fuels, which are polluting degrading environment due to emission greenhouse gases. Hydrogen an identified efficient carrier can be obtained through renewable non-renewable sources. overview sources hydrogen production focuses on water splitting (electrolysis, thermolysis, photolysis) biomass (biological thermochemical) mechanisms presented this study. limitations associated with these discussed. study also looks at some critical factors that hinders scaling up economy globally. Key among issues relating absence a value chain clean hydrogen, storage transportation high cost production, lack international standards, risks investment. ends future research recommendations researchers help enhance technical efficiencies mechanisms, policy direction governments reduce investment sector scale up.

Language: Английский

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Renewable biohydrogen production from lignocellulosic biomass using fermentation and integration of systems with other energy generation technologies

The Science of The Total Environment, Journal Year: 2020, Volume and Issue: 765, P. 144429 - 144429

Published: Dec. 25, 2020

Language: Английский

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Critical challenges in biohydrogen production processes from the organic feedstocks

Biomass Conversion and Biorefinery, Journal Year: 2020, Volume and Issue: 13(10), P. 8383 - 8401

Published: Aug. 20, 2020

Abstract The ever-increasing world energy demand drives the need for new and sustainable renewable fuel to mitigate problems associated with greenhouse gas emissions such as climate change. This helps in development toward decarbonisation. Thus, recent years, hydrogen has been seen a promising candidate global agendas, where production of biohydrogen gains more attention compared fossil-based hydrogen. In this review, using organic waste materials through fermentation, biophotolysis, microbial electrolysis cell gasification are discussed analysed from technological perspective. main focus herein is summarise criticise bibliometric analysis put forward guidelines potential future routes biomass especially materials. research review claims that substantial efforts currently and, future, should on integrated technology processes (i) dark photofermentation, (ii) (MEC) (iii) combined different biowastes. Furthermore, mapping shows biomethanol modelling process growing areas lead zero-carbon soon.

Language: Английский

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Cellulosic and hemicellulosic fractions of sugarcane bagasse: Potential, challenges and future perspective

International Journal of Biological Macromolecules, Journal Year: 2020, Volume and Issue: 169, P. 564 - 582

Published: Dec. 29, 2020

Language: Английский

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Progress and prospects of hydrogen production: Opportunities and challenges

Journal of Electronic Science and Technology, Journal Year: 2021, Volume and Issue: 19(2), P. 100080 - 100080

Published: Jan. 13, 2021

This study presents an overview of the current status hydrogen production in relation to global requirement for energy and resources. Subsequently, it symmetrically outlines advantages disadvantages various routes including fossil fuel/biomass conversion, water electrolysis, microbial fermentation, photocatalysis (PC), terms their technologies, economy, consumption, costs. Considering characteristics infrastructure issues, highlights that onsite is indispensable convenient some special occasions. Finally, briefly summarizes industrialization situation future development research directions, such as theoretical strengthening, renewable raw material development, process coupling, sustainable use.

Language: Английский

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