Bioinspired Effective Prevention of Restacking in Multilayered Graphene Films: Towards the Next Generation of High‐Performance Supercapacitors
Identifieur interne : 003508 ( Istex/Corpus ); précédent : 003507; suivant : 003509Bioinspired Effective Prevention of Restacking in Multilayered Graphene Films: Towards the Next Generation of High‐Performance Supercapacitors
Auteurs : Xiaowei Yang ; Junwu Zhu ; Ling Qiu ; Dan LiSource :
- Advanced Materials [ 0935-9648 ] ; 2011-07-05.
English descriptors
- KwdEn :
- Annealed, Aqueous electrolyte, Bulk form, Capacitance, Carbon materials, Chem, Colloidal chemistry, Colloidal interaction, Common expectation, Current density, Electrochemical, Electrochemical characterization, Electrochemical performance, Electrolyte, Electrolyte solution, Energy density, Exceptional performance, Frequency response, Graphene, Graphene assembly, Graphene paper, Graphene sheets, Gravimetric capacitances, High energy density, High operation rates, High surface area, Individual sheets, Internal resistance, Intersheet, Intersheet attractions, Intrinsic corrugation, Lter membrane, Ltration, Mater, Maximum peak power density, Maximum power density, Nano lett, Nanotechnol, Next generation, Nyquist plots, Open pore structure, Operation voltage, Other carbon, Parallel manner, Pore, Pore structure, Porous carbon, Power density, Ragone plots, Restacking, Room temperature, Ruoff, Supercapacitor, Supercapacitors, Verlag gmbh, Waals attractions, Wang, Water passages.
- Teeft :
- Annealed, Aqueous electrolyte, Bulk form, Capacitance, Carbon materials, Chem, Colloidal chemistry, Colloidal interaction, Common expectation, Current density, Electrochemical, Electrochemical characterization, Electrochemical performance, Electrolyte, Electrolyte solution, Energy density, Exceptional performance, Frequency response, Graphene, Graphene assembly, Graphene paper, Graphene sheets, Gravimetric capacitances, High energy density, High operation rates, High surface area, Individual sheets, Internal resistance, Intersheet, Intersheet attractions, Intrinsic corrugation, Lter membrane, Ltration, Mater, Maximum peak power density, Maximum power density, Nano lett, Nanotechnol, Next generation, Nyquist plots, Open pore structure, Operation voltage, Other carbon, Parallel manner, Pore, Pore structure, Porous carbon, Power density, Ragone plots, Restacking, Room temperature, Ruoff, Supercapacitor, Supercapacitors, Verlag gmbh, Waals attractions, Wang, Water passages.
Abstract
A simple, bioinspired approach to effectively prevent the restacking of chemically converted graphene sheets in multilayered films is presented. The method enables the creation of a new generation of supercapacitors that combine high energy density, high power density, and high operation rates.
Url:
DOI: 10.1002/adma.201100261
Links to Exploration step
ISTEX:6B775F4B5C9055F8715488C4F2B01B1EDB757986Le document en format XML
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density</term><term>Nano lett</term><term>Nanotechnol</term><term>Next generation</term><term>Nyquist plots</term><term>Open pore structure</term><term>Operation voltage</term><term>Other carbon</term><term>Parallel manner</term><term>Pore</term><term>Pore structure</term><term>Porous carbon</term><term>Power density</term><term>Ragone plots</term><term>Restacking</term><term>Room temperature</term><term>Ruoff</term><term>Supercapacitor</term><term>Supercapacitors</term><term>Verlag gmbh</term><term>Waals attractions</term><term>Wang</term><term>Water passages</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Annealed</term><term>Aqueous electrolyte</term><term>Bulk form</term><term>Capacitance</term><term>Carbon materials</term><term>Chem</term><term>Colloidal chemistry</term><term>Colloidal interaction</term><term>Common expectation</term><term>Current density</term><term>Electrochemical</term><term>Electrochemical characterization</term><term>Electrochemical performance</term><term>Electrolyte</term><term>Electrolyte solution</term><term>Energy density</term><term>Exceptional performance</term><term>Frequency response</term><term>Graphene</term><term>Graphene assembly</term><term>Graphene paper</term><term>Graphene sheets</term><term>Gravimetric capacitances</term><term>High energy density</term><term>High operation rates</term><term>High surface area</term><term>Individual sheets</term><term>Internal resistance</term><term>Intersheet</term><term>Intersheet attractions</term><term>Intrinsic corrugation</term><term>Lter membrane</term><term>Ltration</term><term>Mater</term><term>Maximum peak power density</term><term>Maximum power density</term><term>Nano lett</term><term>Nanotechnol</term><term>Next generation</term><term>Nyquist plots</term><term>Open pore structure</term><term>Operation voltage</term><term>Other carbon</term><term>Parallel manner</term><term>Pore</term><term>Pore structure</term><term>Porous carbon</term><term>Power 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A. Stach</json:string><json:string>Z. Y. Yao</json:string><json:string>Q. Wu</json:string><json:string>M. Herrera-Alonso</json:string><json:string>M. Pasquali</json:string><json:string>M. Burghard</json:string><json:string>C. S. Rout</json:string><json:string>D. S. Yu</json:string><json:string>R. K. Prud</json:string><json:string>J. Schmidt</json:string><json:string>A. Chuvilin</json:string><json:string>R. Schlogl</json:string><json:string>J. J. Boland</json:string><json:string>Y. Gogotsi</json:string><json:string>S. Park</json:string><json:string>J. Chmiola</json:string><json:string>K. S. Novoselov</json:string><json:string>G. W. Lu</json:string><json:string>S. Roth</json:string><json:string>U. Kaiser</json:string><json:string>A. F. Hollenkamp</json:string><json:string>E. J. Zimney</json:string><json:string>Y. Talmon</json:string><json:string>P. Simon</json:string><json:string>J. R. Miller</json:string><json:string>G. P. Simon</json:string><json:string>L. M. Dai</json:string><json:string>H. S. Casalongue</json:string><json:string>J. L. Li</json:string><json:string>D. H. Adamson</json:string><json:string>H. M. Cheng</json:string><json:string>M. A. Worsley</json:string><json:string>H. Sai</json:string><json:string>S. Krishnamurthy</json:string><json:string>J. Jagiello</json:string><json:string>A. Govindaraj</json:string><json:string>M. Byrne</json:string><json:string>B. E. Conway</json:string><json:string>R. D. Piner</json:string><json:string>M. B. Muller</json:string><json:string>D. Hugo</json:string><json:string>X. Gou</json:string><json:string>S. Gilje</json:string><json:string>A. G. Pandolfo</json:string><json:string>P. Langston</json:string><json:string>A. Velamakanni</json:string><json:string>E. Kesselman</json:string><json:string>Z. F. Ma</json:string><json:string>S. C. Lin</json:string><json:string>N. Hilal</json:string><json:string>M. M. Chen</json:string><json:string>J. Phys</json:string><json:string>B. C. 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Dikin</json:string></persName><placeName></placeName><ref_url></ref_url><ref_bibl><json:string>Hu et al.[16]</json:string><json:string>[12]</json:string><json:string>[8]</json:string><json:string>[17]</json:string><json:string>[14]</json:string><json:string>[13]</json:string></ref_bibl><bibl></bibl></unitex></namedEntities><ark><json:string>ark:/67375/WNG-BWQFP168-M</json:string></ark><categories><wos><json:string>1 - science</json:string><json:string>2 - physics, condensed matter</json:string><json:string>2 - physics, applied</json:string><json:string>2 - nanoscience & nanotechnology</json:string><json:string>2 - materials science, multidisciplinary</json:string><json:string>2 - chemistry, physical</json:string><json:string>2 - chemistry, multidisciplinary</json:string></wos><scienceMetrix><json:string>1 - applied sciences</json:string><json:string>2 - enabling & strategic technologies</json:string><json:string>3 - nanoscience & nanotechnology</json:string></scienceMetrix><scopus><json:string>1 - Physical Sciences</json:string><json:string>2 - Engineering</json:string><json:string>3 - Mechanical Engineering</json:string><json:string>1 - Physical Sciences</json:string><json:string>2 - Engineering</json:string><json:string>3 - Mechanics of Materials</json:string><json:string>1 - Physical Sciences</json:string><json:string>2 - Materials Science</json:string><json:string>3 - General Materials Science</json:string></scopus></categories><publicationDate>2011</publicationDate><copyrightDate>2011</copyrightDate><doi><json:string>10.1002/adma.201100261</json:string></doi><id>6B775F4B5C9055F8715488C4F2B01B1EDB757986</id><score>1</score><fulltext><json:item><extension>pdf</extension><original>true</original><mimetype>application/pdf</mimetype><uri>https://api.istex.fr/document/6B775F4B5C9055F8715488C4F2B01B1EDB757986/fulltext/pdf</uri></json:item><json:item><extension>zip</extension><original>false</original><mimetype>application/zip</mimetype><uri>https://api.istex.fr/document/6B775F4B5C9055F8715488C4F2B01B1EDB757986/fulltext/zip</uri></json:item><istex:fulltextTEI uri="https://api.istex.fr/document/6B775F4B5C9055F8715488C4F2B01B1EDB757986/fulltext/tei"><teiHeader><fileDesc><titleStmt><title level="a" type="main" xml:lang="en">Bioinspired Effective Prevention of Restacking in Multilayered Graphene Films: Towards the Next Generation of High‐Performance Supercapacitors</title></titleStmt><publicationStmt><authority>ISTEX</authority><publisher>WILEY‐VCH Verlag</publisher><pubPlace>Weinheim</pubPlace><availability><licence>Copyright © 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim</licence></availability><date type="published" when="2011-07-05"></date></publicationStmt><notesStmt><note type="content-type" subtype="brief-communication" source="shortCommunication" scheme="https://content-type.data.istex.fr/ark:/67375/XTP-S9SX2MFS-0">brief-communication</note><note type="publication-type" subtype="journal" scheme="https://publication-type.data.istex.fr/ark:/67375/JMC-0GLKJH51-B">journal</note></notesStmt><sourceDesc><biblStruct type="brief-communication"><analytic><title level="a" type="main" xml:lang="en">Bioinspired Effective Prevention of Restacking in Multilayered Graphene Films: Towards the Next Generation of High‐Performance Supercapacitors</title><author xml:id="author-0000"><persName><forename type="first">Xiaowei</forename><surname>Yang</surname></persName><affiliation>Department of Materials Engineering, ARC Centre of Excellence for Electromaterials Science, Monash University, VIC 3800, Australia<address><country key="AU"></country></address></affiliation></author><author xml:id="author-0001"><persName><forename type="first">Junwu</forename><surname>Zhu</surname></persName><affiliation>Department of Materials Engineering, ARC Centre of Excellence for Electromaterials Science, Monash University, VIC 3800, Australia<address><country key="AU"></country></address></affiliation></author><author xml:id="author-0002"><persName><forename type="first">Ling</forename><surname>Qiu</surname></persName><affiliation>Department of Materials Engineering, ARC Centre of Excellence for Electromaterials Science, Monash University, VIC 3800, Australia<address><country key="AU"></country></address></affiliation></author><author xml:id="author-0003" role="corresp"><persName><forename type="first">Dan</forename><surname>Li</surname></persName><email>dan.li2@monash.edu</email><affiliation>Department of Materials Engineering, ARC Centre of Excellence for Electromaterials Science, Monash University, VIC 3800, Australia<address><country key="AU"></country></address></affiliation><affiliation>Department of Materials Engineering, ARC Centre of Excellence for Electromaterials Science, Monash University, VIC 3800, Australia.</affiliation></author><idno type="istex">6B775F4B5C9055F8715488C4F2B01B1EDB757986</idno><idno type="ark">ark:/67375/WNG-BWQFP168-M</idno><idno type="DOI">10.1002/adma.201100261</idno><idno type="unit">ADMA201100261</idno><idno type="toTypesetVersion">file:ADMA.ADMA201100261.pdf</idno></analytic><monogr><title level="j" type="main">Advanced Materials</title><title level="j" type="alt">ADVANCED MATERIALS</title><idno type="pISSN">0935-9648</idno><idno type="eISSN">1521-4095</idno><idno type="book-DOI">10.1002/(ISSN)1521-4095</idno><idno type="book-part-DOI">10.1002/adma.v23.25</idno><idno type="product">ADMA</idno><imprint><biblScope unit="vol">23</biblScope><biblScope unit="issue">25</biblScope><biblScope unit="page" from="2833">2833</biblScope><biblScope unit="page" to="2838">2838</biblScope><biblScope unit="page-count">6</biblScope><publisher>WILEY‐VCH Verlag</publisher><pubPlace>Weinheim</pubPlace><date type="published" when="2011-07-05"></date></imprint></monogr></biblStruct></sourceDesc></fileDesc><profileDesc><abstract xml:lang="en" style="graphical"><p><hi rend="bold">A simple, bioinspired approach</hi> to effectively prevent the restacking of chemically converted graphene sheets in multilayered films is presented. 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KGaA, Weinheim</copyright><eventGroup><event type="manuscriptReceived" date="2011-01-21"></event><event type="xmlConverted" agent="Converter:JWSART34_TO_WML3G version:3.1.6 mode:FullText" date="2012-08-13"></event><event type="publishedOnlineEarlyUnpaginated" date="2011-05-10"></event><event type="publishedOnlineFinalForm" date="2011-07-01"></event><event type="firstOnline" date="2011-05-10"></event><event type="xmlConverted" agent="Converter:WILEY_ML3G_TO_WILEY_ML3GV2 version:3.8.8" date="2013-12-31"></event><event type="xmlConverted" agent="Converter:WML3G_To_WML3G version:4.1.7 mode:FullText,remove_FC" date="2014-10-14"></event></eventGroup><numberingGroup><numbering type="pageFirst">2833</numbering><numbering type="pageLast">2838</numbering></numberingGroup><correspondenceTo>Department of Materials Engineering, ARC Centre of Excellence for Electromaterials Science, Monash University, VIC 3800, Australia.</correspondenceTo><linkGroup><link type="toTypesetVersion" href="file:ADMA.ADMA201100261.pdf"></link></linkGroup></publicationMeta><contentMeta><countGroup><count type="figureTotal" number="4"></count><count type="referenceTotal" number="21"></count></countGroup><titleGroup><title type="main" xml:lang="en">Bioinspired Effective Prevention of Restacking in Multilayered Graphene Films: Towards the Next Generation of High‐Performance Supercapacitors</title></titleGroup><creators><creator xml:id="au1" creatorRole="author" affiliationRef="#af1"><personName><givenNames>Xiaowei</givenNames><familyName>Yang</familyName></personName></creator><creator xml:id="au2" creatorRole="author" affiliationRef="#af1"><personName><givenNames>Junwu</givenNames><familyName>Zhu</familyName></personName></creator><creator xml:id="au3" creatorRole="author" affiliationRef="#af1"><personName><givenNames>Ling</givenNames><familyName>Qiu</familyName></personName></creator><creator xml:id="au4" creatorRole="author" affiliationRef="#af1" corresponding="yes"><personName><givenNames>Dan</givenNames><familyName>Li</familyName></personName><contactDetails><email>dan.li2@monash.edu</email></contactDetails></creator></creators><affiliationGroup><affiliation xml:id="af1" countryCode="AU" type="organization"><unparsedAffiliation>Department of Materials Engineering, ARC Centre of Excellence for Electromaterials Science, Monash University, VIC 3800, Australia</unparsedAffiliation></affiliation></affiliationGroup><keywordGroup xml:lang="en" type="author"><keyword xml:id="kwd1">graphene</keyword><keyword xml:id="kwd2">supercapacitors</keyword><keyword xml:id="kwd3">solvation forces</keyword><keyword xml:id="kwd4">colloidal interactions</keyword><keyword xml:id="kwd5">bioinspired materials</keyword></keywordGroup><supportingInformation><p>Detailed facts of importance to specialist readers are published as ”Supporting Information”. 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</p><supportingInfoItem><mediaResource alt="supporting information" href="urn-x:wiley:09359648:media:adma201100261:adma_201100261_sm_suppl"></mediaResource><caption>suppl</caption></supportingInfoItem></supportingInformation><abstractGroup><abstract type="graphical" xml:lang="en"><p><b>A simple, bioinspired approach</b> to effectively prevent the restacking of chemically converted graphene sheets in multilayered films is presented. 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