Please use this identifier to cite or link to this item: https://hdl.handle.net/20.500.14279/30623
DC FieldValueLanguage
dc.contributor.authorNikolaidis, Pavlos-
dc.contributor.authorPoullikkas, Andreas-
dc.date.accessioned2023-10-11T09:43:33Z-
dc.date.available2023-10-11T09:43:33Z-
dc.date.issued2023-01-01-
dc.identifier.citationHydrogen Economy: Processes, Supply Chain, Life Cycle Analysis and Energy Transition for Sustainability, 2023, pp. 595 - 627en_US
dc.identifier.isbn9780323995146-
dc.identifier.urihttps://hdl.handle.net/20.500.14279/30623-
dc.description.abstractThe increase of energy demand and reduction in resources for conventional energy generation have promoted the use of renewable energy sources for energy production. As the only carbon-free with the highest energy content compared to any known fuel, H2 is globally accepted as an environmentally benign renewable energy carrier, alternative to fossil fuels. Based on the feedstocks used, the various processes for its production are generally distinguished in reforming, nonreforming, and water-splitting. In the context of sustainable development, electrolytic power-to-hydrogen mechanism constitutes a potential candidate capable of satisfying all aspects of the energy trilemma, namely affordability, reliability, and sustainability, and providing the pathway for 100% renewable and sustainable energy systems. Considering large and cost-efficient centralized hydrogen production plants, some management-based challenges regard the utilization factor, product purity, storage, transport and distribution, and safety issues. However, the flexibility from power-to-hydrogen plant makes it profitable through reasonable operation among multiple energy sectors, while ensuring universal access to energy, reducing the associated with energy greenhouse gas emissions, enhancing the energy security, minimizing overall costs, creating opportunities for more local jobs, and eliminating the risk over nuclear accidents and nuclear proliferation.en_US
dc.language.isoenen_US
dc.relation.ispartofHydrogen Economy: Processes, Supply Chain, Life Cycle Analysis and Energy Transition for Sustainabilityen_US
dc.rights© Elsevieren_US
dc.rightsAttribution-NonCommercial-NoDerivatives 4.0 International*
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/*
dc.subject100% renewable systemsen_US
dc.subjectHydrogen economyen_US
dc.subjectPower-to-hydrogen processen_US
dc.subjectRenewable energy sourcesen_US
dc.subjectWater electrolysisen_US
dc.titlePower-to-hydrogen concepts for 100% renewable and sustainable energy systemsen_US
dc.typeBook Chapteren_US
dc.collaborationCyprus University of Technologyen_US
dc.collaborationCyprus Energy Regulatory Authorityen_US
dc.subject.categoryElectrical Engineering - Electronic Engineering - Information Engineeringen_US
dc.journalsSubscriptionen_US
dc.countryCyprusen_US
dc.subject.fieldEngineering and Technologyen_US
dc.publicationPeer Revieweden_US
dc.identifier.doi10.1016/B978-0-323-99514-6.00013-3en_US
dc.identifier.scopus2-s2.0-85150090581-
dc.identifier.urlhttps://api.elsevier.com/content/abstract/scopus_id/85150090581-
cut.common.academicyear2022-2023en_US
dc.identifier.spage595en_US
dc.identifier.epage627en_US
item.fulltextNo Fulltext-
item.languageiso639-1en-
item.grantfulltextnone-
item.openairecristypehttp://purl.org/coar/resource_type/c_3248-
item.cerifentitytypePublications-
item.openairetypebookPart-
crisitem.author.deptDepartment of Mechanical Engineering and Materials Science and Engineering-
crisitem.author.deptDepartment of Electrical Engineering, Computer Engineering and Informatics-
crisitem.author.facultyFaculty of Engineering and Technology-
crisitem.author.facultyFaculty of Engineering and Technology-
crisitem.author.orcidhttps://orcid.org/0000-0003-3703-4901-
crisitem.author.parentorgFaculty of Engineering and Technology-
crisitem.author.parentorgFaculty of Engineering and Technology-
Appears in Collections:Κεφάλαια βιβλίων/Book chapters
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