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Boosting Oxygen Evolution Reaction by Creating Both Metal Ion and Lattice‐Oxygen Active Sites in a Complex Oxide

dc.contributor.authorZhu, Yinlong
dc.contributor.authorTahini, Hassan
dc.contributor.authorHu, Zhiwei
dc.contributor.authorChen, Zhi-gang
dc.contributor.authorZhou, Wei
dc.contributor.authorKomarek, Alexander C.
dc.contributor.authorLin, Qian
dc.contributor.authorLin, Hong-Ji
dc.contributor.authorChen, Chien-Te
dc.contributor.authorZhong, Yijun
dc.contributor.authorFernandez-Diaz, M. T.
dc.contributor.authorSmith, Sean
dc.contributor.authorWang, Huanting
dc.contributor.authorLiu, Meilin
dc.contributor.authorShao, Zongping
dc.date.accessioned2020-06-16T03:13:53Z
dc.date.issued2019-11-12
dc.date.updated2020-01-12T07:18:29Z
dc.description.abstractDeveloping efficient and low-cost electrocatalysts for the oxygen evolution reaction (OER) is of paramount importance to many chemical and energy transformation technologies. The diversity and flexibility of metal oxides offer numerous degrees of freedom for enhancing catalytic activity by tailoring their physicochemical properties, but the active site of current metal oxides for OER is still limited to either metal ions or lattice oxygen. Here, a new complex oxide with unique hexagonal structure consisting of one honeycomb-like network, Ba4Sr4(Co0.8Fe0.2)4O15 (hex-BSCF), is reported, demonstrating ultrahigh OER activity because both the tetrahedral Co ions and the octahedral oxygen ions on the surface are active, as confirmed by combined X-ray absorption spectroscopy analysis and theoretical calculations. The bulk hex-BSCF material synthesized by the facile and scalable sol-gel method achieves 10 mA cm−2 at a low overpotential of only 340 mV (and small Tafel slope of 47 mV dec−1) in 0.1 m KOH, surpassing most metal oxides ever reported for OER, while maintaining excellent durability. This study opens up a new avenue to dramatically enhancing catalytic activity of metal oxides for other applications through rational design of structures with multiple active sites.en_AU
dc.description.sponsorshipThis work was financially supported by the Defense industrial technology development program (Grant No. JCKY2018605B006), National Nature Science Foundation of China (Grant No. 21576135), the Jiangsu Nature Science Foundation for Distinguished Young Scholars (Grant No. BK20170043), and the Australian Research Council (Discovery Early Career Researcher Award No. DE190100005).en_AU
dc.format.extent8 pagesen_AU
dc.format.mimetypeapplication/pdfen_AU
dc.identifier.issn0935-9648en_AU
dc.identifier.urihttp://hdl.handle.net/1885/205180
dc.language.isoen_AUen_AU
dc.provenancehttp://sherpa.ac.uk/romeo/issn/0935-9648/ Author can archive post-print (ie final draft post-refereeing) with 12 months embargo (Sherpa/Romeo 22/6/2020)
dc.publisherWiley-VCH Verlag GMBHen_AU
dc.relationhttp://purl.org/au-research/grants/arc/DE190100005en_AU
dc.rights© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. https://authorservices.wiley.com/author-resources/Journal-Authors/licensing/self-archiving.html This is the peer reviewed version of the following article Yinlong Zhu et al, Boosting Oxygen Evolution Reaction by Creating Both Metal Ion and Lattice‐Oxygen Active Sites in a Complex Oxide, Advanced Materials 32 (1) 12 November 2019, doi 10.1002/adma.201905025, which has been published in final form at https://doi.org/10.1002/adma.201905025. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions (Publisher journal website 22/6/2020)en_AU
dc.sourceAdvanced Materialsen_AU
dc.subjectcomplex oxides, coordination environment, dual active sites, honeycomblike structures, oxygen evolution reactionen_AU
dc.titleBoosting Oxygen Evolution Reaction by Creating Both Metal Ion and Lattice‐Oxygen Active Sites in a Complex Oxideen_AU
dc.typeJournal articleen_AU
dcterms.accessRightsOpen Access
local.bibliographicCitation.issue1en_AU
local.bibliographicCitation.startpage1905025en_AU
local.contributor.affiliationZhu, Yinlong, Nanjing Tech Universityen_AU
local.contributor.affiliationTahini, Hassan, College of Science, The Australian National Universityen_AU
local.contributor.affiliationHu, Zhiwei, Max Planck Institute for Chemical Physics of Solidsen_AU
local.contributor.affiliationChen, Zhi-gang, Centre for Future Materials, University of Southern Queenslanden_AU
local.contributor.affiliationZhou, Wei, Nanjing Tech Universityen_AU
local.contributor.affiliationKomarek, Alexander C., Max Planck Institute for Chemical Physics of solidsen_AU
local.contributor.affiliationLin, Qian, Nanjing Tech Universityen_AU
local.contributor.affiliationLin, Hong-Ji, National Synchrotron Radiation Research Centeren_AU
local.contributor.affiliationChen, Chien-Te, National Synchrotron Radiation Research Centeren_AU
local.contributor.affiliationZhong, Yijun, Dept of Chemical Engineering, Curtin Universityen_AU
local.contributor.affiliationFernandez-Diaz , M. T., Institut Laue-Langevin (ILL)en_AU
local.contributor.affiliationSmith, Sean, College of Science, The Australian National Universityen_AU
local.contributor.affiliationWang, Huanting, Monash Universityen_AU
local.contributor.affiliationLiu, Meilin, Georgia Institute of Technologyen_AU
local.contributor.affiliationShao, Zongping, Curtin Universityen_AU
local.contributor.authoruidTahini, Hassan, u1057037en_AU
local.contributor.authoruidSmith, Sean, u1056946en_AU
local.description.notesImported from ARIESen_AU
local.identifier.absfor030601 - Catalysis and Mechanisms of Reactionsen_AU
local.identifier.absseo859801 - Management of Gaseous Waste from Energy Activities (excl. Greenhouse Gases)en_AU
local.identifier.ariespublicationu9912193xPUB497en_AU
local.identifier.citationvolume32en_AU
local.identifier.doi10.1002/adma.201905025en_AU
local.identifier.essn1521-4095en_AU
local.publisher.urlhttps://www.wiley.com/en-gben_AU
local.type.statusAccepted Versionen_AU

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