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Exploring the frontiers of electrochemical $CO_{2}$ conversion: a comprehensive review

creativework.datePublished2025-10-15
dc.contributor.authorAshraf, Shahid
dc.contributor.authorGohar, Osama
dc.contributor.authorKhan, Muhammad Zubair
dc.contributor.authorTariq, Urooj
dc.contributor.authorAhmad, Jawad
dc.contributor.authorAwan, Ramsha Javed
dc.contributor.authorZheng, Kun
dc.contributor.authorUr Rehman, Junaid
dc.contributor.authorAbdul Karim, Muhammad Ramzan
dc.contributor.authorIshfaq, Hafiz Ahmad
dc.contributor.authorSaid, Zafar
dc.contributor.authorMotola, Martin
dc.contributor.authorHan, Ning
dc.contributor.authorHanif, Muhammad Bilal
dc.contributor.departmentWydział Energetyki i Paliw
dc.date.issued2025
dc.description.abstractThe electrochemical conversion of carbon dioxide into valuable products is pivotal for maintaining the global carbon cycle and mitigating global warming. This review explores the advancements in electrochemical $CO_{2}$ conversion, particularly focusing on producing methanol, ethanol, and n-propanol using various catalysts such as metals, metal oxides, metal alloys, and metal organic frameworks. Additionally, it covers the photoelectrochemical (PEC) conversion of $CO_{2}$ into alcohols. The primary objective is to identify efficient electrocatalysts for ethanol, methanol, and n-propanol production, prioritizing selectivity, stability, Faradaic efficiency (FE), and current density. Notable catalysts include PtxZn nanoalloys, which exhibit an FE of ∼81.4 ​% for methanol production, and trimetallic Pt/Pb/Zn nanoalloys, aimed at reducing Pt costs while enhancing catalyst stability and durability. Metal oxide catalysts like thin film $Cu_{2}O/CuO$ on nickel foam and $Cu_{2}O/ZnO$ achieve FE values of ∼38 ​% and ∼16.6 ​% for methanol production, respectively. Copper-based metal-organic frameworks, such as Cu@ $Cu_{2}O$, demonstrate an FE of ∼45 ​% for methanol production. Similarly, $Ag_{0.14}/Cu_{0.86}$ and Cu–Zn alloys exhibit FEs of ∼63 ​% and ∼46.6 ​%, respectively, for ethanol production. Notably, n-propanol production via Pd–Cu alloy and $graphene/ZnO/Cu_{2}O$ yields FEs of ∼13.7 ​% and ∼23 ​%, respectively. Furthermore, the review discusses recent advancements in PEC reactor design, photoelectrodes, reaction mechanisms, and catalyst durability. By evaluating the efficiency of these devices in liquid fuel production, the review addresses challenges and prospects in $CO_{2}$ conversion for obtaining various valuable products.en
dc.description.versionwersja wydawnicza
dc.identifier.doihttps://doi.org/10.1016/j.nanoms.2024.05.005
dc.identifier.urihttps://repo.agh.edu.pl/handle/AGH/115737
dc.language.isoeng
dc.relation.ispartofNano Materials Science
dc.rightsAttribution-NonCommercial-NoDerivatives 4.0 Internationalen
dc.rights.accessotwarty dostęp
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/
dc.subjectCO2 conversionen
dc.subjectelectrochemicalpl
dc.subjectphotoelectrochemicalpl
dc.subjectmethanolpl
dc.subjectethanoln-propanolpl
dc.titleExploring the frontiers of electrochemical $CO_{2}$ conversion: a comprehensive review
dc.typeartykuł
dspace.entity.typePublication
organization.identifier.ror03ha2q922
project.funder.nameNarodowe Centrum Nauki (NCN)
project.identifier2021/43/D/ST5/00824
project.nameProjektowanie niestechiometrycznych kationowo perowskitów podwójnych z nanokatalitycznym wydzielaniem in situ dla poprawy wydajności symetrycznych ogniw SOFC
project.program.nameSonata 17
publicationissue.issueNumberIss. 5
publicationissue.paginationpp. 565-581
publicationvolume.volumeNumberVol. 7
relation.isAuthorOfPublication91fa7b0f-11f0-43b9-a020-cae7e3a7b835
relation.isAuthorOfPublication.latestForDiscovery91fa7b0f-11f0-43b9-a020-cae7e3a7b835
relation.isOrgUnitOfPublicationf2ffae00-dd3a-402a-9571-3a432c7f77f8
relation.isOrgUnitOfPublication.latestForDiscoveryf2ffae00-dd3a-402a-9571-3a432c7f77f8

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