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Please use this identifier to cite or link to this item: https://hdl.handle.net/1959.11/55901
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dc.contributor.authorHuang, Xiang Longen
dc.contributor.authorHussain, Tanveeren
dc.contributor.authorLiu, Hanwenen
dc.contributor.authorKaewmaraya, Thanayuten
dc.contributor.authorXu, Maowenen
dc.contributor.authorLiu, Hua Kunen
dc.contributor.authorDou, Shi Xueen
dc.contributor.authorWang, Zhimingen
dc.date.accessioned2023-08-30T01:16:16Z-
dc.date.available2023-08-30T01:16:16Z-
dc.date.issued2023-07-21-
dc.identifier.citationInorganic Chemistry Frontiers, 10(14), p. 4241-4251en
dc.identifier.issn2052-1553en
dc.identifier.issn2052-1545en
dc.identifier.urihttps://hdl.handle.net/1959.11/55901-
dc.description.abstract<p>The shuttle effect of soluble polysulfides is a critical challenge that hinders the realization of pragmatic room-temperature sodium–sulfur (RT Na–S) batteries. To surmount this intractable issue, carbon nanorods decorated with highly sulfiphilic nanosized cementite (nano-Fe<sub>3</sub>C) are employed to serve as the role of S host. The nano-Fe<sub>3</sub>C strongly interacts with soluble polysulfide intermediates via Fe–S bonds to block their shuttling action. More significantly, the nano-Fe<sub>3</sub>C enables the dredging of these polysulfides via its electrocatalytic effect, which is accompanied by improved redox kinetics. Moreover, the hierarchical porous carbon nanorod substrate promotes the fast transport of electrons and accommodates the dramatic volumetric fluctuation of the active materials. As a result, the nano-Fe<sub>3</sub>C-decorated S cathode demonstrates outstanding cyclability (capacity retention of 373 mA h g<sub>−1</sub> over 900 cycles at 1.0 A g<sub>−1</sub> ).This work presents an excellent highly efficient electrocatalyst that realizes improved RT Na–S batteries.</p>en
dc.languageenen
dc.publisherRoyal Society of Chemistryen
dc.relation.ispartofInorganic Chemistry Frontiersen
dc.titleDredging sodium polysulfides using a Fe3C electrocatalyst to realize improved room-temperature Na–S batteriesen
dc.typeJournal Articleen
dc.identifier.doi10.1039/D3QI00661Aen
local.contributor.firstnameXiang Longen
local.contributor.firstnameTanveeren
local.contributor.firstnameHanwenen
local.contributor.firstnameThanayuten
local.contributor.firstnameMaowenen
local.contributor.firstnameHua Kunen
local.contributor.firstnameShi Xueen
local.contributor.firstnameZhimingen
local.profile.schoolSchool of Science and Technologyen
local.profile.emailthussai3@une.edu.auen
local.output.categoryC1en
local.record.placeauen
local.record.institutionUniversity of New Englanden
local.publisher.placeUnited Kingdomen
local.format.startpage4241en
local.format.endpage4251en
local.peerreviewedYesen
local.identifier.volume10en
local.identifier.issue14en
local.contributor.lastnameHuangen
local.contributor.lastnameHussainen
local.contributor.lastnameLiuen
local.contributor.lastnameKaewmarayaen
local.contributor.lastnameXuen
local.contributor.lastnameLiuen
local.contributor.lastnameDouen
local.contributor.lastnameWangen
dc.identifier.staffune-id:thussai3en
local.profile.orcid0000-0003-1973-4584en
local.profile.roleauthoren
local.profile.roleauthoren
local.profile.roleauthoren
local.profile.roleauthoren
local.profile.roleauthoren
local.profile.roleauthoren
local.profile.roleauthoren
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local.identifier.unepublicationidune:1959.11/55901en
local.date.onlineversion2023-06-28-
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
dc.identifier.academiclevelAcademicen
local.title.maintitleDredging sodium polysulfides using a Fe3C electrocatalyst to realize improved room-temperature Na–S batteriesen
local.relation.fundingsourcenoteAuthors acknowledge the financial support from the National Key Research and Development Program of China (2019YFB2203400), the “111 Project” (B20030), National Natural Science Foundation of China (no. 22179109), and Australian Research Council (DP200102215).en
local.output.categorydescriptionC1 Refereed Article in a Scholarly Journalen
local.search.authorHuang, Xiang Longen
local.search.authorHussain, Tanveeren
local.search.authorLiu, Hanwenen
local.search.authorKaewmaraya, Thanayuten
local.search.authorXu, Maowenen
local.search.authorLiu, Hua Kunen
local.search.authorDou, Shi Xueen
local.search.authorWang, Zhimingen
local.uneassociationYesen
local.atsiresearchNoen
local.sensitive.culturalNoen
local.year.available2023en
local.year.published2023en
local.fileurl.closedpublishedhttps://rune.une.edu.au/web/retrieve/8b65571d-be46-41c9-aaec-fd5d41da8d17en
local.subject.for2020340701 Computational chemistryen
local.subject.seo2020170899 Renewable energy not elsewhere classifieden
local.profile.affiliationtypeExternal Affiliationen
local.profile.affiliationtypeUNE Affiliationen
local.profile.affiliationtypeExternal Affiliationen
local.profile.affiliationtypeExternal Affiliationen
local.profile.affiliationtypeExternal Affiliationen
local.profile.affiliationtypeExternal Affiliationen
local.profile.affiliationtypeExternal Affiliationen
local.profile.affiliationtypeExternal Affiliationen
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