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Journal articles on the topic 'Renewable hydrogen production'

Author: Grafiati
Published: 4 June 2021
Last updated: 25 July 2025

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1

Turner, John, George Sverdrup, Margaret K. Mann, et al. "Renewable hydrogen production." International Journal of Energy Research 32, no. 5 (2008): 379–407. http://dx.doi.org/10.1002/er.1372.

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2

Modi, Prabha. "A Brief theoretical approach on Green Hydrogen Production." INTERANTIONAL JOURNAL OF SCIENTIFIC RESEARCH IN ENGINEERING AND MANAGEMENT 08, no. 04 (2024): 1–5. http://dx.doi.org/10.55041/ijsrem30175.

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Many different technical techniques can be used to manufacture hydrogen from both renewable and nonrenewable feed supplies while reducing greenhouse gas emissions. Hydrogen is employed in upcoming low-carbon energy systems since it emits relatively little carbon. The bulk of the present green hydrogen activities are geared toward the possibility of a green hydrogen market. Green hydrogen and origin guarantees have been defined using various approaches. These vary according on the following: the carbon financial statements' characteristics; the emission threshold at which hydrogen is classified
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3

Mulla, Rafiq, and Charles W. Dunnill. "From Renewable Energy to Renewable Fuel: A Sustainable Hydrogen Production." Energy and Earth Science 3, no. 2 (2020): p49. http://dx.doi.org/10.22158/ees.v3n2p49.

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Hydrogen, a zero-emission fuel and the universal energy vector, can be easily produced from many different energy sources. It is a storable, transportable product that can be used on demand to overcome supply and demand imbalances. As of today, most of the hydrogen produced comes from natural gas; the production process itself is in fact not so pollution free. As the world is looking for a low carbon future, researchers have therefore been looking for more sustainable, environmentally friendly pathways of hydrogen production by using renewable energy sources such as solar and wind. Among the d
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Dinh, Huyen N. "(Invited) Hydrogen Consortium: Advancements in Renewable Hydrogen Production." ECS Meeting Abstracts MA2024-02, no. 59 (2024): 3928. https://doi.org/10.1149/ma2024-02593928mtgabs.

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HydroGEN Energy Materials Network (EMN) is an U.S. Department of Energy (DOE) EERE Hydrogen and Fuel Cell Technologies Office (HFTO)-funded consortium that aims to accelerate the discovery and development of advanced water splitting materials (AWSM) for clean, low-cost hydrogen production. Materials innovations are key to enhancing performance, durability, and cost of hydrogen generation technologies. HydroGEN is focused on low technology readiness level AWS technologies, including low- (alkaline exchanged membrane electrolysis) and high-temperature electrolysis (proton-conducting solid oxide
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5

Lima, Alessandro, Jorge Torrubia, Alicia Valero, and Antonio Valero. "Non-Renewable and Renewable Exergy Costs of Water Electrolysis in Hydrogen Production." Energies 18, no. 6 (2025): 1398. https://doi.org/10.3390/en18061398.

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Hydrogen production via water electrolysis and renewable electricity is expected to play a pivotal role as an energy carrier in the energy transition. This fuel emerges as the most environmentally sustainable energy vector for non-electric applications and is devoid of CO2 emissions. However, an electrolyzer’s infrastructure relies on scarce and energy-intensive metals such as platinum, palladium, iridium (PGM), silicon, rare earth elements, and silver. Under this context, this paper explores the exergy cost, i.e., the exergy destroyed to obtain one kW of hydrogen. We disaggregated it into non
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6

Bamberger, Joachim, Ti-Chiun Chang, Brian Mason, et al. "Reliable cost-efficient distributed energy systems with a high renewable penetration: a techno-economic case study for remote off-grid regional coal seam gas extraction." APPEA Journal 58, no. 2 (2018): 493. http://dx.doi.org/10.1071/aj17238.

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As our energy systems evolve with the adoption of more variable renewable energy resources, so will our oil and gas industry play a pivotal role in what is expected to be a lengthy transitional phase to a greater mix of renewables with a reliance on fast, reliable gas peaking power generation, which have lower greenhouse gas emissions, and short delivery periods to construct. Oil and gas companies are also rapidly moving towards becoming integrated energy companies supplying a mix of gas, oil, photovoltaic power, wind power and hydrogen, coupling these into the electrical and gas grids. We dis
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7

Durcansky, Peter, Radovan Nosek, Richard Lenhard, and Branislav Zvada. "Hydrogen Production Possibilities in Slovak Republic." Applied Sciences 12, no. 7 (2022): 3525. http://dx.doi.org/10.3390/app12073525.

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Slovak Republic is a member of the European Union and is a part of the European energy market. Although Slovakia contributes only marginally to global emissions, there is an effort to meet obligations from the Paris climate agreement to reduce greenhouse gases. As in many countries, power industry emissions dominate Slovakia’s emissions output but are partly affected and lowered by the share of nuclear energy. The transition from fossil fuels to renewables is supported by the government, and practical steps have been taken to promote the wide use of renewable resources, such as biomass or sola
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8

Hallenbeck, Patrick C. "Microbial paths to renewable hydrogen production." Biofuels 2, no. 3 (2011): 285–302. http://dx.doi.org/10.4155/bfs.11.6.

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9

Bilgen, E. "Domestic hydrogen production using renewable energy." Solar Energy 77, no. 1 (2004): 47–55. http://dx.doi.org/10.1016/j.solener.2004.03.012.

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10

Balat, Mustafa, and Nuray Ozdemir. "New and Renewable Hydrogen Production Processes." Energy Sources 27, no. 13 (2005): 1285–98. http://dx.doi.org/10.1080/009083190519564.

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11

Perkins, Christopher, and Alan W. Weimer. "Solar-thermal production of renewable hydrogen." AIChE Journal 55, no. 2 (2009): 286–93. http://dx.doi.org/10.1002/aic.11810.

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12

Bonafé, Ernesto, Marco Conte, and Katharina Bouchaar. "Hydrogen Valleys: Assessing the EU Legal and Financial Frameworks that Enable the Hydrogen Economy." Global Energy Law and Sustainability 4, no. 1-2 (2023): 96–114. http://dx.doi.org/10.3366/gels.2023.0095.

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To achieve the target of 10 million tonnes of renewable hydrogen production in the European Union (EU) by 2030, the REPowerEU Plan commits the EU to double the number of hydrogen ‘valleys’, which will contribute to accelerating the production of renewable hydrogen to replace natural gas, coal and oil in hard-to-decarbonise economic sectors. This article reviews ongoing efforts to lay down a regulatory framework to move from natural gas to renewable hydrogen and, not least, to define renewable hydrogen. As a strategic net-zero industry, renewable hydrogen is to grow and flourish in hydrogen val
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13

Martino, Marco, Concetta Ruocco, Eugenio Meloni, Pluton Pullumbi, and Vincenzo Palma. "Main Hydrogen Production Processes: An Overview." Catalysts 11, no. 5 (2021): 547. http://dx.doi.org/10.3390/catal11050547.

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Due to its characteristics, hydrogen is considered the energy carrier of the future. Its use as a fuel generates reduced pollution, as if burned it almost exclusively produces water vapor. Hydrogen can be produced from numerous sources, both of fossil and renewable origin, and with as many production processes, which can use renewable or non-renewable energy sources. To achieve carbon neutrality, the sources must necessarily be renewable, and the production processes themselves must use renewable energy sources. In this review article the main characteristics of the most used hydrogen producti
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14

Gardner, Dale. "Hydrogen production from renewables." Renewable Energy Focus 9, no. 7 (2009): 34–37. http://dx.doi.org/10.1016/s1755-0084(09)70036-5.

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15

Chaturvedi, Shalini, and Pragnesh N. Dave. "Photocatalytic Hydrogen Production." Materials Science Forum 764 (July 2013): 151–68. http://dx.doi.org/10.4028/www.scientific.net/msf.764.151.

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Hydrogen is the efficient storage of solar energy in chemical fuels. It is essential for the large-scale utilization of solar energy systems. The production of clean and renewable hydrogen via photocatalysis has received much attention due to the increasing global energy need. In the chapter we are mainly discussed about photocatalytic method for hydrogen production. All other reported method and mechanism of hydrogen production are also summarized here.
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16

Mohamed Elshafei, Ali, and Rawia Mansour. "Green Hydrogen as a Potential Solution for Reducing Carbon Emissions: A Review." Journal of Energy Research and Reviews 13, no. 2 (2023): 1–10. http://dx.doi.org/10.9734/jenrr/2023/v13i2257.

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Hydrogen is one of the types of energy discovered in recent decades, which is based on the electrolysis of water in order to separate hydrogen from oxygen. These include grey hydrogen, black hydrogen, blue hydrogen, yellow hydrogen, turquoise hydrogen, and green hydrogen. Generally, hydrogen can be extracted from a variety of sources, including fossil fuels and biomass, water, or a combination of the two. Green hydrogen has the potential to be a critical enabler of the global transition to sustainable energy and zero-emissions economies. Worldwide, there is unprecedented momentum to realize hy
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17

Deng, Yimin, Helei Liu, Hui Luo, Liju Bai, Miao Yang, and Jan Baeyens. "Solar-driven Redox Hydrogen Production." E3S Web of Conferences 635 (2025): 01004. https://doi.org/10.1051/e3sconf/202563501004.

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The climate crisis requires urgent actions to reduce the global temperature. Renewable energy and electro-chemicals are expected to play a growing role in sustainable power solutions moving forward. Hydrogen-based approaches are projected to emerge as the main long-term strategy. With declining expenses for solar panels and wind energy systems, building electrolyzers near renewable power sites has emerged as a viable hydrogen production method. A fossil-free approach for generating H2 would involve utilizing carbon-neutral raw materials. Preliminary studies examined this concept through methan
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18

Daswani, Bhrat Bobby, and Andrew P. Campbell. "Comparative analysis of hydrogen production pathways for emethanol synthesis to decarbonise industry." Australian Energy Producers Journal 64, no. 2 (2024): S130—S134. http://dx.doi.org/10.1071/ep23146.

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Methane pyrolysis and water electrolysis offer alternative hydrogen pathways to methane reforming that utilise renewable power and avoid generating carbon dioxide (CO2). On a scope 1 and 2 basis, both technologies have the potential to generate carbon neutral emethanol fuel when combined with biogenic CO2. However, pyrolysis requires significantly less energy and has a lower capital expenditure (CAPEX). Being a more nascent technology, it also has upside potential for cost reductions and valorisation of the solid carbon by-product can yield lower hydrogen costs than the incumbent technology, h
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19

Silva, F. C., L. S. Martins, and J. V. C. Vargas. "Sustainable and renewable hydrogen production from recycled aluminum." Revista de Engenharia Térmica 22, no. 2 (2023): 36. http://dx.doi.org/10.5380/reterm.v22i2.91878.

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The whole world has been suffering strong consequences related to climate change. The intense use of fossil fuels in the chemical and automotive industries have put the environment in jeopardy. Thus, the industry has achieved a point of no return and it is urgent the development of renewable and sustainable technologies. Hydrogen has been pointed as a key component of the new era in industry since it can be produced in a clean and sustainable way. Currently the development of hydrogen fuel cells technology has put the automotive sector ahead of the chemical industries in relation to studies re
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20

Song, Chunyan, Bo Zhang, Wenchao Cai, et al. "Techno-economic analysis of hydrogen production systems based on solar/wind hybrid renewable energy." Journal of Physics: Conference Series 2723, no. 1 (2024): 012002. http://dx.doi.org/10.1088/1742-6596/2723/1/012002.

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Abstract With the popularity of renewable energy, more and more countries and regions are utilizing renewable energy to produce hydrogen. However, renewable energy hydrogen production systems are often large in capacity and equipment, and require rational design as well as performance analysis of the system to satisfy the technicalities while ensuring the economics. In this paper, 12 different renewable energy systems for hydrogen production, including 6 grid-connected systems and 6 off-grid systems, are designed considering solar and wind energy as the main renewable energy sources in a place
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21

Nguyen, Van Nhu, and Nhu Tung Truong. "Technologies for production of green hydrogen and hydrogen based synthetic fuels." Petrovietnam Journal 12 (December 28, 2021): 23–39. http://dx.doi.org/10.47800/pvj.2021.12-03.

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Hydrogen is an essential material/fuel for industry and energy conversion. The processes for producing hydrogen depend on the raw materials and energy source used. In terms of climate impacts, the most promising hydrogen production method is water electrolysis. The regenerative electrolysis process depends on the carbon intensity of the electricity and the efficiency of converting that electricity into hydrogen. The development of technologies to extract hydrogen (from conventional and renewable resources) tends to optimise the water electrolysis process using renewable energies by extending m
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22

Lencho, Negeso Geleto, Zhang Qingran, Ensah Amara, and Menbere Asmare Wondim. "Techno-Economic Analysis of Green Hydrogen Production: A Review Focusing on the Geographical and Technological Factors." European Journal of Applied Science, Engineering and Technology 3, no. 2 (2025): 233–60. https://doi.org/10.59324/ejaset.2025.3(2).20.

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This review explores the transformative potential of green hydrogen as a key solution in the global shift toward sustainable energy. By using renewable energy sources to power water electrolysis, green hydrogen provides a carbon-neutral alternative to fossil fuels, effectively addressing environmental concerns and the growing demand for clean energy. The review delves into the techno-economic analysis of green hydrogen production, focusing specifically on the geographical and technological factors influencing hydrogen systems' cost, feasibility, and scalability. Critical geographical factors s
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23

Leshchenko, I. Ch. "Levelised cost of hydrogen production in Ukraine." Problems of General Energy 2021, no. 2 (2021): 4–11. http://dx.doi.org/10.15407/pge2021.02.004.

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The overview of decarbonization technologies of the gas industry, particularly Power-to-Gas technologies using renewable or excess electricity to produce hydrogen via water electrolysis is presented. Also, a comparative analysis of the main types of electrolyzers for hydrogen production – alkaline and with proton exchange membrane (PEM) is presented, and the conclusion that the PEM electrolyzers using renewable electricity is advisable for implementation in Ukraine. A comparative analysis of available most reasonable data sources regarding estimates of "green" hydrogen production cost is prese
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24

Rossetti, Ilenia. "Hydrogen Production by Photoreforming of Renewable Substrates." ISRN Chemical Engineering 2012 (November 22, 2012): 1–21. http://dx.doi.org/10.5402/2012/964936.

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This paper focuses on the application of photocatalysis to hydrogen production from organic substrates. This process, usually called photoreforming, makes use of semiconductors to promote redox reactions, namely, the oxidation of organic molecules and the reduction of H+ to H2. This may be an interesting and fully sustainable way to produce this interesting fuel, provided that materials efficiency becomes sufficient and solar light can be effectively harvested. After a first introduction to the key features of the photoreforming process, the attention will be directed to the needs for material
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25

Dorjgotov, A., B. Ulziidelger, J. Yunseong, K. Oh Chan, J. Ok Sung, and S. Yong-Gun. "Hydrogen production possibility using Mongolian renewable energy." IOP Conference Series: Earth and Environmental Science 291 (June 27, 2019): 012029. http://dx.doi.org/10.1088/1755-1315/291/1/012029.

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26

Patel, Ronak, and Sanjay Patel. "Renewable hydrogen production from butanol: a review." Clean Energy 1, no. 1 (2017): 90–101. http://dx.doi.org/10.1093/ce/zkx008.

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27

Patel, Pinakin, Ludwig Lipp, Fred Jahnke, Ed Heydorn, and Franklin Holcomb. "Co-Production of Renewable Hydrogen and Electricity." ECS Transactions 17, no. 1 (2019): 569–80. http://dx.doi.org/10.1149/1.3142787.

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28

O’Neill, Keelan T., Fuyu Jiao, Saif Al Ghafri, Eric F. May, and Michael L. Johns. "Stable electrolytic hydrogen production using renewable energy." Energy Conversion and Management 321 (December 2024): 119070. http://dx.doi.org/10.1016/j.enconman.2024.119070.

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29

LODHI, M. "Hydrogen production from renewable sources of energy." International Journal of Hydrogen Energy 12, no. 7 (1987): 461–68. http://dx.doi.org/10.1016/0360-3199(87)90042-5.

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30

Levin, David B., and Richard Chahine. "Challenges for renewable hydrogen production from biomass." International Journal of Hydrogen Energy 35, no. 10 (2010): 4962–69. http://dx.doi.org/10.1016/j.ijhydene.2009.08.067.

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31

Kelvin Edem Bassey and Chinedu Ibegbulam. "MACHINE LEARNING FOR GREEN HYDROGEN PRODUCTION." Computer Science & IT Research Journal 4, no. 3 (2023): 368–85. http://dx.doi.org/10.51594/csitrj.v4i3.1253.

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Green hydrogen production, achieved through the electrolysis of water using renewable energy sources, represents a promising pathway towards sustainable energy systems. However, optimizing the electrolysis process to enhance efficiency and reduce costs remains a significant challenge. This study explores the application of machine learning (ML) techniques to develop AI-driven models that optimize the electrolysis process, thereby improving the efficiency and cost-effectiveness of green hydrogen production. Machine learning models can analyze complex datasets generated during the electrolysis p
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32

Patel, Prachi, and Kathy Ayers. "Electrolysis for hydrogen production." MRS Bulletin 44, no. 09 (2019): 684–85. http://dx.doi.org/10.1557/mrs.2019.210.

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The lightest element has carried a heavy burden for half a century. Expectations for the hydrogen economy, first proposed in the 1970s, have been high. But hydrogen as a renewable, low-carbon fuel for vehicles, heating, and energy storage has remained evasive, held back by high costs, low efficiency, and a lack of infrastructure and storage technologies.
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Liponi, Angelica, Andrea Baccioli, Lorenzo Ferrari, and Umberto Desideri. "Techno-economic analysis of hydrogen production from PV plants." E3S Web of Conferences 334 (2022): 01001. http://dx.doi.org/10.1051/e3sconf/202233401001.

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Hydrogen production through electrolysis from renewable sources is expected to play an important role to achieve the reduction targets of carbon dioxide emissions set for the next decades. Electrolysers can use the renewable energy surplus to produce green hydrogen and contribute to making the electrical grid more stable. Hydrogen can be used as medium-long term energy storage, converted into other fuels, or used as feedstock in industry thus contributing to decarbonise hard-to-abate-sectors. However, due to the intermittent and variable nature of solar and wind power, the direct coupling of e
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34

Miyagawa, Tomonori, and Mika Goto. "Hydrogen Production Cost Forecasts since the 1970s and Implications for Technological Development." Energies 15, no. 12 (2022): 4375. http://dx.doi.org/10.3390/en15124375.

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This study reviews the extant literature on hydrogen production cost forecasts to identify and analyze the historical trend of such forecasts in order to explore the feasibility of wider adoption. Hydrogen is an important energy source that can be used to achieve a carbon-neutral society, but the widespread adoption of hydrogen production technologies is hampered by the high costs. The production costs vary depending on the technology employed: gray, renewable electrolysis, or biomass. The study identifies 174 production cost forecast data points from articles published between 1979 and 2020 a
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Sukriti, Petkar, Chopde Janhavi, Chandanshive Pranay, and Ingole Prashant. "Solar Thermochemical Hydrogen Production Plant." International Journal of Innovative Science and Research Technology 7, no. 4 (2022): 1075–80. https://doi.org/10.5281/zenodo.6565221.

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Our main objective of the project was to study all the existing methods of hydrogen production and find most feasible and renewable methods among all. We studied them, compared and analyzed each of the methods that are widely known or used for the production of hydrogen gas and came to a conclusion that steam methane reforming method of hydrogen production is the most widely ysed and most efficient method among the rest. We have introduced the usage of solar energy in the steam methane reforming reaction in the place of utility. However, steam reforming method of methane process is considered
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36

Stenina, Irina, and Andrey Yaroslavtsev. "Modern Technologies of Hydrogen Production." Processes 11, no. 1 (2022): 56. http://dx.doi.org/10.3390/pr11010056.

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Transitioning to energy-saving and renewable energy sources is impossible without accelerated development of hydrogen energy and hydrogen technologies. This review summarizes the state-of-the-art and recent advances of various hydrogen production processes, including but not limited to thermochemical and electrolytic processes. Their opportunities and limitations, operating conditions, and catalysts are discussed. Nowadays, most hydrogen is still produced by steam reforming of methane, its partial oxidation, or coal gasification. Considerable attention is also paid to natural gas pyrolysis. Ho
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37

Schiro, Fabio, Anna Stoppato, and Alberto Benato. "Potentialities of hydrogen enriched natural gas for residential heating decarbonization and impact analysis on premixed boilers." E3S Web of Conferences 116 (2019): 00072. http://dx.doi.org/10.1051/e3sconf/201911600072.

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Nowadays, decarbonization of energy economy is a topical theme and several pathways are under discussion. Gaseous fuels will play a primary role during this transition, and the production of renewable or low carbon-impact gaseous fuels is necessary to deal with this challenge. Decarbonization will be sustained by an increasing share of renewables, which production intermittency can be critical for the energy system. Renewable hydrogen generation is a viable solution since this energy vector can be produced from electricity with a fast response and injected in the existing natural gas infrastru
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38

Lejnieks, Ilgmārs, and Modrīte Pelše. "Correlation Between Major Economic Indicators and Green Hydrogen Production in the EU." Rural Sustainability Research 52, no. 347 (2024): 126–35. https://doi.org/10.2478/plua-2024-0019.

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Abstract The European Union’s Green Deal agenda emphasises the major importance of cleaner and more environmentally friendly energy sources for further economic development. Hydrogen is one of the potential renewable fuels that can replace fossil fuels in a variety of economic applications. The green hydrogen production across Europe is a key factor in achieving this goal. The aim of the study is to determine the influence of the connection between the availability of renewable energy sources, innovation, and economic development patterns on hydrogen production advancement. The research provid
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Deng, Yimin, Shuo Li, Helei Liu, Huili Zhang, and Jan Baeyens. "Recent Research in Solar-Driven Hydrogen Production." Sustainability 16, no. 7 (2024): 2883. http://dx.doi.org/10.3390/su16072883.

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Climate concerns require immediate actions to reduce the global average temperature increase. Renewable electricity and renewable energy-based fuels and chemicals are crucial for progressive de-fossilization. Hydrogen will be part of the solution. The main issues to be considered are the growing market for H2 and the “green” feedstock and energy that should be used to produce H2. The electrolysis of water using surplus renewable energy is considered an important development. Alternative H2 production routes should be using “green” feedstock to replace fossil fuels. We firstly investigated thes
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40

Wu, Qinglin. "Analysis of several main hydrogen production technologies." IOP Conference Series: Earth and Environmental Science 1011, no. 1 (2022): 012005. http://dx.doi.org/10.1088/1755-1315/1011/1/012005.

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Abstract With economic development, social progress, and population growth, mankind’s demand for energy increases. Fossil fuels such as coal, oil, and natural gas are accelerating consumption, and these fossil fuels are non-renewable, and their reserves are very limited. If we continue to use fossil fuels uncontrollably, it will inevitably cause acid rain and global warming. As a renewable energy source, hydrogen energy has the least environmental pollution, and hydrogen energy can be dispersed in large quantities and converted from renewable energy. At present, hydrogen production technology
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Hamed, Ali Mahmoud, Tengku Nordayana Akma Tuan Kamaruddin, Nabilah Ramli, and Mohd Firdaus Abdul Wahab. "A review on blue and green hydrogen production process and their life cycle assessments." IOP Conference Series: Earth and Environmental Science 1281, no. 1 (2023): 012034. http://dx.doi.org/10.1088/1755-1315/1281/1/012034.

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Abstract Green and blue hydrogen are two types of hydrogen generated from renewable energy sources and fossil fuels, respectively. Green hydrogen is created by splitting water molecules into oxygen and hydrogen using renewable energy sources such as wind, solar or nuclear power in a process known as electrolysis. Blue hydrogen, on the other hand, is produced by reforming natural gas and capturing and storing the resulting carbon emissions. The production of both green and blue hydrogen has implications for the environment, and a life cycle assessment (LCA) can be used to evaluate the environme
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42

Schoonman, Joop, and Dana Perniu. "Nanostructured materials for solar hydrogen production." Analele Universitatii "Ovidius" Constanta - Seria Chimie 25, no. 1 (2014): 32–38. http://dx.doi.org/10.2478/auoc-2014-0006.

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Abstract One of the main requirements for a future Hydrogen Economy is a clean and efficient process for producing hydrogen using renewable energy sources. Hydrogen is a promising energy carrier because of its high energy content and clean combustion. In particular, the production of hydrogen from water and solar energy, i.e., photocatalysis and photoelectrolysis, represent methods for both renewable and sustainable energy production. Here, we will present the principles of photocatalysis and the PhotoElectroChemical cell (PEC cell) for water splitting, along with functional materials. Defect
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43

Malykh, E. B. "Worldwide development of renewable energy in the context of Russia’s geo-economic interests." Economics and Management 28, no. 3 (2022): 255–66. http://dx.doi.org/10.35854/1998-1627-2022-3-255-266.

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Aim. The presented study aims to assess the impact of the worldwide development of renewable energy on Russia’s geo-economic interests and to formulate proposals for reducing the negative aspects of such influence.Tasks. The authors examine materials related to the topic of the study; analyze trends in the development of renewable energy sources (RES) worldwide; identify threats to hydrocarbon exports from Russia associated with the development of RES; show Russia’s export potential in the hydrogen market; assess threats associated with plans for the production of hydrogen based on RES in the
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44

Imbayah, Ibrahim, Mashhood Hasan, Hala El-Khozondare, Mohamed Khaleel, Abdulgader Alsharif, and Abdussalam Ahmed. "Review paper on Green Hydrogen Production, Storage, and Utilization Techniques in Libya." Solar Energy and Sustainable Development Journal 13, no. 1 (2024): 1–21. http://dx.doi.org/10.51646/jsesd.v13i1.165.

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the world is currently facing energy-related challenges due to the cost and pollution of non-renewable energy sources and the increasing power demand from renewable energy sources. Green hydrogen is a promising solution in Libya for converting renewable energy into usable fuel. This paper covers the types of hydrogen, its features, preparation methods, and uses. Green hydrogen production is still limited in the world due to safety requirements because hydrogen has a relatively low ignition temperature and an extensive ignition range and is considered a hazardous element, the lack of infrastruc
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Klymenko, V. N., T. T. Suprun, and Ye N. Oliinyk. "FEASIBILITY STUDY OF THE USE OF “GREEN” HYDROGEN FOR THE PRODUCTION OF SYNTHETIC RENEWABLE METHANE." Energy Technologies & Resource Saving 83, no. 2 (2025): 33–41. https://doi.org/10.33070/etars.2.2025.03.

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An effective means of decarbonizing industry is the methanation technology, i.e. the conversion of carbon dioxide and hydrogen into methane, which can be used as a fuel or raw material. To obtain synthetic renewable methane with a low carbon footprint, carbon dioxide must be of organic origin, and hydrogen must be produced using renewable energy sources (solar, wind). The issues of obtaining and using precisely “green” hydrogen for the production of synthetic renewable methane using Power-to-Gas technology are considered in the article. The greatest attention is paid to the economic features o
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46

Karmaker, Shamal Chandra, Andrew Chapman, Kanchan Kumar Sen, Shahadat Hosan, and Bidyut Baran Saha. "Renewable Energy Pathways toward Accelerating Hydrogen Fuel Production: Evidence from Global Hydrogen Modeling." Sustainability 15, no. 1 (2022): 588. http://dx.doi.org/10.3390/su15010588.

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Fossil fuel consumption has triggered worries about energy security and climate change; this has promoted hydrogen as a viable option to aid in decarbonizing global energy systems. Hydrogen could substitute for fossil fuels in the future due to the economic, political, and environmental concerns related to energy production using fossil fuels. However, currently, the majority of hydrogen is produced using fossil fuels, particularly natural gas, which is not a renewable source of energy. It is therefore crucial to increase the efforts to produce hydrogen from renewable sources, rather from the
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Woodward, Jonathan, Kimberley A. Cordray, Maria Blanco-Rivera, Susan M. Mattingly, and Barbara R. Evans. "Enzymatic Hydrogen Production: Conversion of Renewable Resources for Energy Production." Energy & Fuels 14, no. 1 (2000): 197–201. http://dx.doi.org/10.1021/ef990126l.

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Yang, Tianqi, Xianglin Yan, Wenchao Cai, et al. "Parametric Study and Optimization of Hydrogen Production Systems Based on Solar/Wind Hybrid Renewable Energies: A Case Study in Kuqa, China." Sustainability 16, no. 2 (2024): 896. http://dx.doi.org/10.3390/su16020896.

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Based on the concept of sustainable development, to promote the development and application of renewable energy and enhance the capacity of renewable energy consumption, this paper studies the design and optimization of renewable energy hydrogen production systems. For this paper, six different scenarios for grid-connected and off-grid renewable energy hydrogen production systems were designed and analyzed economically and technically, and the optimal grid-connected and off-grid systems were selected. Subsequently, the optimal system solution was optimized by analyzing the impact of the load d
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Siddique, MNI. "Review of Hydrogen production: Opportunities and Difficulties." Environmental Sciences and Ecology: Current Research (ESECR 6, no. 1 (2025): 1–2. https://doi.org/10.54026/esecr/10111.

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Social, ecological, political, and economic issues are important. The availability of environmentally friendly, safe, and reliable energy sources is extremely important to the company for sustainable growth and good quality of life. Our constantly increasing energy requirements are caused by substantial population and economic growth, increasing the use of fossil fuels, a significant portion of this demand, but increasing the issue of increased Greenhouse Gas Emissions (GHG) and resource depreciation. These challenges require a global shift from traditional energy sources to renewable energy s
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Crabtree, G. W., and M. S. Dresselhaus. "The Hydrogen Fuel Alternative." MRS Bulletin 33, no. 4 (2008): 421–28. http://dx.doi.org/10.1557/mrs2008.84.

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AbstractThe cleanliness of hydrogen and the efficiency of fuel cells taken together offer an appealing alternative to fossil fuels. Implementing hydrogen-powered fuel cells on a significant scale, however, requires major advances in hydrogen production, storage, and use. Splitting water renewably offers the most plentiful and climate-friendly source of hydrogen and can be achieved through electrolytic, photochemical, or biological means. Whereas presently available hydride compounds cannot easily satisfy the competing requirements for on-board storage of hydrogen for transportation, nanoscienc
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