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Enhancement of the photoelectrochemical water splitting by perovskite BiFeO3 via interfacial engineering

dc.contributor.authorLiu, Guanyu
dc.contributor.authorKaruturi, Siva Krishna
dc.contributor.authorChen, Hongjun
dc.contributor.authorWang, Dunwei
dc.contributor.authorAger, Joel W
dc.contributor.authorSimonov, A. N.
dc.contributor.authorTricoli, Antonio
dc.date.accessioned2021-02-22T03:25:20Z
dc.date.issued2020
dc.date.updated2020-11-15T07:17:42Z
dc.description.abstractFerroelectric semiconductors like BiFeO3 are increasingly being investigated for applications in solar energy conversion and storage due to their intrinsic ability to induce ferroelectric polarization-driven separation of the photogenerated charge carriers resulting in above-bandgap photovoltages. Nevertheless, the BiFeO3 has been commonly prepared using complex and expensive fabrication techniques, e.g., epitaxial growth, radio frequency sputtering and pulsed laser deposition, which are not economically viable for large-scale production. Herein, we report a facile and scalable method for the fabrication of porous perovskite BiFeO3 photoanodes, as well as sequential interfacial engineering methods to enhance their photoelectrochemical performance for water splitting. Upon atomic layer deposition of a TiO2 overlayer and photo-assisted electrodeposition of a cobalt oxide/oxyhydroxide co-catalyst, the photocurrent density of the engineered photoanode for oxygen evolution reaction (1 M NaOH) significantly increased from negligible photocurrent of the pristine BiFeO3 to 0.16 mA cm−2 at 1.23 V vs. reversible hydrogen electrode (RHE) under simulated 1 sun irradiation (100 mW cm−2, AM1.5G spectrum). Furthermore, such functionalization of the BiFeO3 photoanodes shifts the photoelectrochemical oxidation onset potential by 0.7 V down to 0.6 V vs. RHE. The significantly enhanced photoelectro-oxidation activity is facilitated by the improved charge transfer and electrochemical kinetics.en_AU
dc.description.sponsorshipD.W. acknowledges support from the National Science Foundation (CBET 1703662, United States). A.N.S. are grateful for the financial support from the Australian Research Council via the Center of Excellence for Electromaterials Science (CE140100012). J.W.A. acknowledges the financial support of the Singapore National Research Foundation under its Campus for Research Excellence and Technological Enterprise (CREATE) program through the Cambridge Center for Advanced Research and Education in Singapore (CARES) and the Berkeley Educational Alliance for Research in Singapore (BEARS) eCO2EP program. Access to the facilities of the Centre for Advanced Microscopy (CAM) with funding through the Australian Microscopy and Microanalysis Research Facility (AMMRF) is gratefully acknowledged. The authors also acknowledge the Australian National Fabrication Facility (ANFF) for financial support and access to experimental facilitiesen_AU
dc.format.mimetypeapplication/pdfen_AU
dc.identifier.issn0038-092Xen_AU
dc.identifier.urihttp://hdl.handle.net/1885/223934
dc.language.isoen_AUen_AU
dc.publisherPergamon-Elsevier Ltden_AU
dc.relationhttp://purl.org/au-research/grants/arc/DP150101939en_AU
dc.relationhttp://purl.org/au-research/grants/arc/DE160100569en_AU
dc.rights© 2020 International Solar Energy Society. Published by Elsevier Ltd. All rights reserved.en_AU
dc.sourceSolar Energyen_AU
dc.source.urihttps://www.sciencedirect.com/science/article/pii/S0038092X20303637?via%3Dihuben_AU
dc.subjectBiFeO3 Interfacial engineeringen_AU
dc.subjectFerroelectricen_AU
dc.subjectPerovskiteen_AU
dc.subjectPhotoelectrochemical water splittingen_AU
dc.subjectInterfacial engineeringen_AU
dc.titleEnhancement of the photoelectrochemical water splitting by perovskite BiFeO3 via interfacial engineeringen_AU
dc.typeJournal articleen_AU
local.bibliographicCitation.lastpage203en_AU
local.bibliographicCitation.startpage198en_AU
local.contributor.affiliationLiu, Guanyu, College of Engineering and Computer Science, ANUen_AU
local.contributor.affiliationKaruturi, Siva, College of Engineering and Computer Science, ANUen_AU
local.contributor.affiliationChen, Hongjun, College of Engineering and Computer Science, ANUen_AU
local.contributor.affiliationWang, Dunwei, Boston Collegeen_AU
local.contributor.affiliationAger, Joel W, University of California at Berkeleyen_AU
local.contributor.affiliationSimonov, A. N., Monash Universityen_AU
local.contributor.affiliationTricoli, Antonio, College of Engineering and Computer Science, ANUen_AU
local.contributor.authoruidLiu, Guanyu, u5323264en_AU
local.contributor.authoruidKaruturi, Siva, u5684485en_AU
local.contributor.authoruidChen, Hongjun, u1020039en_AU
local.contributor.authoruidTricoli, Antonio, u5276175en_AU
local.description.embargo2099-12-31
local.description.notesImported from ARIESen_AU
local.identifier.absfor090605 - Photodetectors, Optical Sensors and Solar Cellsen_AU
local.identifier.absseo850303 - Hydrogen Production from Renewable Energyen_AU
local.identifier.ariespublicationa383154xPUB11094en_AU
local.identifier.citationvolume202en_AU
local.identifier.doi10.1016/j.solener.2020.03.117en_AU
local.publisher.urlhttps://www.sciencedirect.com/science/article/pii/S0038092X20303637?via%3Dihuben_AU
local.type.statusPublished Versionen_AU

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