Recent Progress in Fabrication and Structural Design of Thermal Conductive Polymer Composites

Yuan-Kai Du; Zheng-Xue Shi; Shan Dong; Hui Jin; Xue Ke; Pei Zhao; Bing-Bing Jiang; Feng You

doi:10.1007/s10118-023-3057-5

Your Location：

Home >

Browse articles >

Recent Progress in Fabrication and Structural Design of Thermal Conductive Polymer Composites

REVIEW | Updated：2024-02-20

- Recent Progress in Fabrication and Structural Design of Thermal Conductive Polymer Composites
  Enhanced Publication
- Recent Progress in Fabrication and Structural Design of Thermal Conductive Polymer Composites
- 高分子科学（英文版） 2024年42卷第3期页码：277-291
- Affiliations：
  
  a.Hubei Key Laboratory of Plasma Chemistry and Advanced Materials, School of Material Science and Engineering, Wuhan Institute of Technology, Wuhan 430205, China
  b.Key Laboratory of Green Preparation and Application of Functional Materials, Ministry of Education, Hubei University, Wuhan 430062, China
  c.Institute of Molecular Aggregation Science, Tianjin University, Tianjin 300072, China
- Author bio：
  
  youfeng.mse@wit.edu.cn
- Funds：
  
  This work was financially supported by Graduate Innovation Fund of Wuhan Institute of Technology, Natural Science Foundation of Hubei Province (No. 2022CFB630) and Open Fund of Key Laboratory of Green Preparation and Application for Functional Materials, Ministry of Education (Hubei University) (No. 202105).
- DOI：10.1007/s10118-023-3057-5
  中图分类号：
Scan for full text
Du, Y. K.; Shi, Z. X.; Dong, S.; Jin, H.; Ke, X.; Zhao, P.; Jiang, B. B.; You, F. Recent progress in fabrication and structural design of thermal conductive polymer composites. Chinese J. Polym. Sci. 2024, 42, 277–291

Yuan-Kai Du, Zheng-Xue Shi, Shan Dong, et al. Recent Progress in Fabrication and Structural Design of Thermal Conductive Polymer Composites[J]. Chinese Journal of Polymer Science, 2024,42(3):277-291.
Du, Y. K.; Shi, Z. X.; Dong, S.; Jin, H.; Ke, X.; Zhao, P.; Jiang, B. B.; You, F. Recent progress in fabrication and structural design of thermal conductive polymer composites. Chinese J. Polym. Sci. 2024, 42, 277–291 DOI： 10.1007/s10118-023-3057-5.

Yuan-Kai Du, Zheng-Xue Shi, Shan Dong, et al. Recent Progress in Fabrication and Structural Design of Thermal Conductive Polymer Composites[J]. Chinese Journal of Polymer Science, 2024,42(3):277-291. DOI： 10.1007/s10118-023-3057-5.

摘要

The progress of design fabrication and performance of thermal conductive polymer composites was reviewed in three directions in this work, including the introduction of single filler, hybrid fillers and complex multiphase structures.

Abstract

In recent years, the demand direction for electronic equipment has expanded into embedded and miniaturized devices. The heat radiation problem has become one of the most significant factors for hindering the development of electronic devices. Since heat radiation material is one of the important components in electronic devices, the demand for enhancing thermal conductivity is also increasingly urgent. Research on thermal conductive polymer composites has become a major direction for developing functional composites. This work reviewed the recent progress in the fabrication of thermal conductive polymer composites. Five different structures are presented, including the using of single fillers, hybrid fillers, double threshold percolation structure, segregated structure and other complex multiphase structures. Specifically, the preparation of high-performance thermal conductive polymer composites was introduced through the combination of various thermal conductive fillers. Finally, the development direction of high thermal conductive polymer composites was briefly explored.

关键词

Keywords

Thermal conductive polymerHybrid fillersPolymer compositeThermal resistance

references

Leung,S.N.Thermallyconductivepolymercompositesandnanocomposites:processing-structure-propertyrelationships.Compos. B Eng.2018, 150,78−92..

Xu,H.J.;Xing,Z.B.;Wang,F.Q.;Cheng,Z.M.Reviewonheatconduction,heatconvection,thermalradiationandphasechangeheattransferofnanofluidsinporousmedia:fundamentalsandapplications.Chem. Eng. Sci.2019, 195,462−483..

Qian,X.;Zhou,J.W.;Zhou,G.Phonon-engineeredextremethermalconductivitymaterials.Nat. Mater.2021, 9,1188−1202..

Mehra,N;Mu,L.W.Zhu,J.H.Developingheatconductionpathwaysthroughshortpolymerchainsinahydrogenbondedpolymersystem.Compos. Sci. Technol.2017, 148,97−105..

MehraN,Mu,L.W.;Ji,T.;Yang,X.T.;Kong,J.;Gu,J.W.;Zhu,J.H.Thermaltransportinpolymericmaterialsandacrosscompositeinterfaces.Appl. Mater. Today2018, 12,92−130..

Huang,X.Y.;Jiang,P.;Tanaka,T.Areviewofdielectricpolymercompositeswithhighthermalconductivity.IEEE Electr. Insul. M.2011, 27,8−16..

Li,M.;Liu,B.W.;Liu,ZJ.;Xiao,Y.M.;Guo,H.M.;An,Z.H.;Wang,L.D.;James,T.D.ReducingheatConductionenhancesthephotothermalefficiencyofupcycledadsorbents.Adv. Funct. Mater.2023, 33,2209987..

Chen,G.Non-Fourierphononheatconductionatthemicroscaleandnanoscale.Nat. Rev. Phys.2021, 3,555−569..

Guo,Y.Q.;Ruan,K.P.;Shi,X.T.;Yang,X.T.;Gu,J.M.Factorsaffectingthermalconductivitiesofthepolymersandpolymercomposites:areview.Compos. Sci. Technol.2020, 193,108134..

Kausar,A.Thermallyconductingpolymer/nanocarbonandpolymer/inorganicnanoparticlenanocomposite:areview.Polym. Plast. Techol. Mater.2020, 59,895..

Guo,Y.Q.;Ruan,K.P.;Wang,G.S.;Gu,J.W.Advancesandmechanismsinpolymercompositestowardthermalconductionandelectromagneticwaveabsorption.Sci. Bull.2023, 68,1195−1212..

Gu,J.;Ruan,K.P.Breakingthroughbottlenecksforthermallyconductivepolymercomposites:aperspectiveforintrinsicthermalconductivity,interfacialthermalresistanceandtheoretics.Nano-Micro Lett.2021, 13,110..

Swartz,E.T.;Pohl,R.O.Thermalboundaryresistance.Rev. Mod. Phys.1989, 61,605..

Chen,G.Thermalconductivityandballistic-phonontransportinthecross-planedirectionofsuperlattices.Phy. Rev. B1998, 57,14958..

Bi,D.M.;Chen,H.X.;Ye,T.Influencesoftemperatureandcontactpressureonthermalcontactresistanceatinterfacesatcryogenictemperatures.Cryogenics2012, 52,403−409..

Ruan,K.P.;Shi,X.T.;Guo,Y.Q.;Gu,J.M.Interfacialthermalresistanceinthermallyconductivepolymercomposites:areview.Compos. Commun.2020, 22,100518..

Tan,X.;Yuan,Q.L.Qiu,;M.T.;Yu,N.Jiang,C.T.Lin,J.H.;Dai,W.Rationaldesignofgraphene/polymercompositeswithexcellentelectromagneticinterferenceshieldingeffectivenessandhighthermalconductivity:aminireview.J. Mater. Sci. Technol.2022, 117,238−250..

Wang,Z.Y.;Sun,X.;Wang,Y.;Liu,J.D.;Zhang,C.;Zhao,Z.B.;Du,X.Y.Ahigh-performancethermallyconductiveandelectricallyinsulatingsilver@siloxane/graphene/epoxycompositesatlowfillercontent:Fabrication,mechanismstudyofinsulationandthermalconductivityenhancement.Ceram. Int.2023, 49,2871−2880..

Qi,W.;Liu,M.;Wu,J.L.;Xie,Q.;Chen,L.;Yang,X.;Shen,B.Y.;Bian,X.M.;Song,W.L.Promotingthethermaltransport viaunderstandingtheintrinsicrelationbetweenthermalconductivityandinterfacialcontactprobabilityinthepolymericcompositeswithhybridfillers.Compos. Part. B-Eng.2022, 232,109613..

Xie.B.;Zhu,Y.W.;Marwat,M.A.;Zhang.S.J.;Zhang,L.;Zhang,H.B.Tailoringtheenergystorageperformanceofpolymernanocompositeswithaspectratiooptimized1Dnanofillers.J. Mater. Chem. A2018, 6,20356−20364..

Li,C.;Zeng,X.L.;Tan,L.Y.;Yao,Y.M.;Zhu,D.L.;Sun,R.;Xu,J.B.;Wong,C.P.Three-dimensionalinterconnectedgraphenemicrosphereasfillersforenhancingthermalconductivityofpolymer.Chem. Eng. J.2019, 368,79−87..

An,L.L.;Yu,Y.L.;Cai,Q.R.;Mateti,S.;Li,L.H.;Chen,Y.I.Hexagonalboronnitridenanosheets:preparation,heattransportpropertyandapplicationasthermallyconductivefillers.Prog. Mater. Sci.2023, 138,101154..

Liu,M.J.;Chiang,S.W.;Chu,X.D.;Li,J.;Gan,L.;He,Y.B.;Li,B.H.;Kang,F.Y.;Du,H.D.Polymercompositeswithenhancedthermalconductivityviaorientedboronnitrideandaluminahybridfillersassistedby3-Dprinting.Ceram. Int.2020, 46,20810−20818..

Maxwell,J.C.A treatise on electricity and magnetism,ClarendonPress,Oxford, 1873 ,p.478..

Bruggemann,D.A.G.Dielectricconstantandconductivityofmixturesofisotropicmaterial.Ann. Phys.1935, 24,636−664..

Agari,Y.;Uno,T.Estimationonthermalconductivitiesoffilledpolymers.J. Appl. Polym. Sci.1986, 32,5705−5712..

Zhang,G.Q.;Xia,X.P.;Wang,H.;Tao,Y.;Tao,G.L.;Tu,S.T.;Wu,H.P.Apercolationmodelofthermalconductivityforfilledpolymercomposites.J. Compos. Mater.2010, 44,963−970..

Guo,Y.Q.;Ruan,K.P.;Gu,J.W.Controllablethermalconductivityincompositesbyconstructingthermalconductionnetworks.Mater. Today Phys.2021, 20,100449..

Li,A.;Zhang,C.;Zhang,Y.F.Thermalconductivityofgraphene-polymercomposites,mechanisms,properties,andapplications.Polymers2017, 9,437..

Shen,Z.M.;Feng,J.C.Highlythermallyconductivecompositefilmsbasedonnanofibrillatedcellulose in situcoatedwithasmallamountofsilvernanoparticle.ACS Appl. Mater. Interfaces2018, 10,24193−24200..

Krupa,I.;Cecen,V.;Boudenne,A.;Prokes,J.;Novak,I.Themechanicalandadhesivepropertiesofelectricallyandthermallyconductivepolymericcompositesbasedonhighdensitypolyethylenefilledwithnickelpowder.Mater. Des.2013, 51,620−628..

Wang,Y.;Chen,Q.M.;Liu,C.;Li,S.;Wu,W.HighlyenhancedthermalconductivityofTPUcompositeswithsegregatednetworkconstructedbythein-situreductionofcopper.J. Alloy. Compd.2023, 941,168801..

Chen,W.;Wang,Z.F.;Zhi,C.Y.;Zhang,W.J.Highthermalconductivityandtemperatureprobingofcoppernanowire/upconversionnanoparticles/epoxycomposite.Compos. Sci. Technol.2016, 130,63−69..

Ota,S.;Harada,M.Thermalconductivityenhancementofliquidcrystallineepoxy/MgOcompositesbyformationofhighlyorderednetworkstructure.J. Appl. Polym. Sci.2020, 138,50367..

Wondu,E.;Lule,Z.;Kim,J.Thermalconductivityandmechanicalpropertiesofthermoplasticpolyurethane-/silane-modifiedAl2O3compositefabricated viameltcompounding.Polymers2019, 11,1103..

Yeo,H.;Islam,A.M.;You,N.H.;Ahn,S.;Goh,M.;Hahn,J.R.;Jang,S.G.Characteristiccorrelationbetweenliquidcrystallineepoxyandaluminafilleronthermalconductingproperties.Compos. Sci. Technol.2017, 141,99−105..

Guo,L.C.;Zhang,Z.Y.;Kang,R.Y.;Chen,Y.P.;Hou,X.;Wu,Y.M.;Wang,M.J.;Wang,B.;Cui,J.F.;Jiang,N.;Lin,C.T.;Yu,J.H.Enhancedthermalconductivityofepoxycompositesfilledwithtetrapod-shapedZnO.RSC Adv.2018, 8,12337−12343..

Yuan,Y.;Li,Z.T.;Cao,L.;Tang,B.;Zhang,S.R.ModificationofSi3N4ceramicpowdersandfabricationofSi3N4/PTFEcompositesubstratewithhighthermalconductivity.Ceram. Int.2019, 45,16569−16576..

Lee,W.;Kim,J.Highlythermalconductiveandelectricalinsulatingepoxycompositeswithathree-dimensionalfillernetworkbysinteringsilvernanowiresonaluminumnitridesurface.Polymers2021, 13,694..

Zhang,Z.Y.;Wu,D.;Yang,H.;Qu,H.C.;Yao,C.;Liu,F.J.;Yu,P.;Yao,J.L.;You,F.;Jiang,X.L.Remarkableenhancementinthermalperformanceofpolypropylenecarbonatebyusingexfoliatedboronnitridenanosheets.Chem. Eng. J.2022, 450,138247..

Liu,B.C.;Li,Y.B.;Fei,T.;Han,S.;Xia,C.B.;Shan,Z.H.;Jiang,J.L.Highlythermallyconductivepolystyrene/polypropylene/boronnitridecompositeswith3Dsegregatedstructurepreparedbysolution-mixingandhot-pressingmethod.Chem. Eng. J.2020, 385,123829..

Zhang,X.W.;Zhang,B.;Sun,M.M.;Li,J.H.;Liu,C.Z.Preparationandthermalconductivitypropertiesofhigh-temperatureresistancepolyimidecompositefilmsbasedonsilvernanowires-decoratedmulti-walledcarbonnanotubes. J.Mater.Sci. Mater. Electron.2022, 33,1577−1588..

Lin,Y.;Lang,F.;Zeng,D.;You,Y.L.;Li,D.X.;Xiao,C.G.EffectsofmodifiedgrapheneonpropertyoptimizationinthermalconductivecompositesbasedonPPS/PA6blend.Soft Mater.2021, 19,457−467..

Wang,Y.Y.;Zhang,X.;Ding,X.;Li,Y.;Zhang,P.;Shu,M.T.;Zhang,Q.;Gong,Y.;Zheng,K.;Wu,B.;Tian,X.Y.Enhancedthermalconductivityofcarbonnitride-dopedgraphene/polyimidecompositefilm viaa"deciduous-like"strategy.Compos. Sci. Technol.2021, 205,108693..

Ma,J.K.;Shang,T.Y.;Ren,L.L.;Yao,Y.M.;Zhang,T.;Xie,J.Q.;Zhang,B.T.;Zeng,X.L.;Sun,R.;Xu,J.B.;Wong,C.P.Through-planeassemblyofcarbonfibersinto3Dskeletonachievingenhancedthermalconductivityofathermalinterfacematerial.Chem. Eng. J.2020, 380,122550..

Zhan,C.;Cui,W.Z.;Li,L.J.;Quan,X.J.;Zhang,Y.Q.;Xiao,F.Dual-Alignedcarbonnanofiberscaffoldsasheatconductionpathtoenhancethermalconductivityofpolymercomposites.Compos. Sci. Technol.2023, 231,109823..

Wang,X.G.;Zhang,C.Y.;Wang,K.;Huang,Y.Q.;Chen,Z.F.Highlyefficientphotothermalconversioncapricacidphasechangemicrocapsule:Siliconcarbidemodifiedmelamineureaformaldehyde.J. Colloid Interface Sci.2021, 582,30−40..

Li,C.L.;Guo,H.L.;Tian,X.;Tian,X.G.Transientresponseforahalf-spacewithvariablethermalconductivityanddiffusivityunderthermalandchemicalshock.J. Therm. Stresses2017, 40,389−401..

Guo,Y.Q.;Yang,X.T.;Ruan,K.P.;Kong,J.;Dong,M.Y.;Zhang,J.X.;Gu,J.W.;Guo,Z.H.Reducedgrapheneoxideheterostructuredsilvernanoparticlessignificantlyenhancedthermalconductivitiesinhot-pressedelectrospunpolyimidenanocomposites.ACS Appl. Mater. Interfaces2019, 11,25465−25473..

Nayak,S.K.;Mohanty,S.;Nayak,S.K.Silver(Ag)nanoparticle-decoratedexpandedgraphite(EG)epoxycomposite:evaluatingthermalandelectricalproperties.J. Mater. Sci.-Mater. Electron.2019, 30,20574−20587..

Wang,Y.;Wu,W.;Drummer,D.;Liu,C.;Shen,W.T.;Tomiak,F.;Schneider,K.;Liu,X.R.;Chen,Q.M.Highlythermallyconductivepolybenzoxazinecompositesbasedonboronnitrideflakesdepositedwithcopperparticles.Mater. Des.2020, 191,108698..

Liu,C.;Wu,W.;Drummer,D.;Shen,W.T.;Wang,Y.;Schneider,K.;Tomiak,F.ZnOnanowire-decoratedAl2O3hybridsforimprovingthethermalconductivityofpolymercomposites.J. Mater. Chem. C2020, 8,5380−5388..

Lule,Z.;Kim,J.Thermallyconductiveandhighlyrigidpolylacticacid(PLA)hybridcompositefilledwithsurfacetreatedalumina/nano-sizedaluminumnitride.Compos. Part A: Appl. Sci. Manuf.2019, 124,105506..

Liu,Y.C.;Lu,M.P.;Wu,K.;Yao,S.;Du,X.X.;Chen,G.K.;Zhang,Q.;Liang,L.Y.;Lu,M.G.Anisotropicthermalconductivityandelectromagneticinterferenceshieldingofepoxynanocompositesbasedonmagneticdrivingreducedgrapheneoxide@Fe3O4.Compos. Sci. Technol.2019, 174,1−10..

Niu,H.Y.;Guo,H.C.;Ren,Y.J.;Ren,L.C.;Lv,R.C.;Kang,L.;Bashir,A.;Bai,S.L.SphericalaggregatedBN/AlNfilledsiliconecompositeswithenhancedthrough-planethermalconductivityassistedbyvortexflow.Chem. Eng. J.2022, 430,133155..

Yao,Y.M.;Sun,J.J.;Zeng,X.L.;Sun,R.;Xu,J.B.;Wong,C.P.Constructionof3Dskeletonforpolymercompositesachievingahighthermalconductivity.Small2018, 14,1704044..

Jiang,X.L.;Ma,P.F.;Zhou,C.;Zhu,W.W.;You,F.;Yao,C.;Liu,F.J.SimultaneouslyenhancingthethermalconductivityanddielectricconstantofBN/CFhybridfilledpolypropylene/polystyrenecomposites via in situreactiveprocessing.Polym. Compos.2019, 41,1234−1241..

Xie,X.;Yang,D.Achievinghighthermalconductivityandsatisfactoryinsulatingpropertiesofelastomercompositesbyself-assemblingBN@GOhybrids.Polymers2023, 15,523..

Wu,H.C.;Zhou,W.Q.;Liu,Q.;Cai,X.;Qu,Z.H.;Li,P.;Hu,D.;Jia,X.L.Highpressurehomogenizationofgrapheneandcarbonnanotubeforthermalconductivepolyethylenecompositewithalowfillercontent.J. Appl. Polym. Sci.2021, 139,51838..

Jiang,Z.L.;Liu,X.;Xu,Q.F.;Zhou,C.Y.;Shang,Y.S.;Zhang,H.B.Thermalconductivesegregatedmulti-scalenetworkconstructedbyball-millingand in-situpolymerizationinPEEK/MWCNT/graphitecomposite.Compos. Commun.2022, 29,101035..

Song,J.N.;Zhang,Y.Verticallyalignedsiliconcarbidenanowires/reducedgrapheneoxidenetworksforenhancingthethermalconductivityofsiliconerubbercomposites.Compos. Pt. A Appl. Sci. Manuf.2020, 133,105873..

Ouyang,Y.G.;Bai,L.Y.;Tian,H.F.;Li,X.F.;Yuan,F.L.Recentprogressofthermalconductiveploymercomposites,Al2O3fillers,propertiesandapplications.Compos. Pt. A Appl. Sci. Manuf.2022, 152,106685..

Su,F.;Zhang,L.;Li,C.Z.High-thermal-conductionandlow-costcompositeoriginatedfromthetightpackingstructureofboronnitridesheetsandbinaryaluminaballs.Polym. Compos.2021, 42,3562−3571..

Kozlovskiy,A.L.;Zdorovets,M.V.;Uglov,V.V.Studyofchangesinopticalandheat-conductingpropertiesofAlNceramicsunderirradiationwithKr15+andXe22+heavyion.Nanomaterials2020, 10,2375..

Du,J.J.;Dai,W.J.;Kou,H.J.;Wu,P.F.;Xing,W.L.;Zhang,Y.Z.;Zhang,C.AlNcoatingswithhighthermalconductivityandexcellentelectricalpropertiesforthermalmanagementdevices.Ceram. Int.2023, 49,16740−16752..

Akkoyun,S.;Akkoyun,M.Improvementofthermalconductivityofrigidpolyurethanefoamswithaluminumnitridefiller.Cell. Polym.2021, 40,87..

Lee,S.;Park,D.;Kim,J.3D-printedsurface-modifiedaluminumnitridereinforcedthermallyconductivecompositeswithenhancedthermalconductivityandmechanicalstrength.Polym. Adv. Technol.2022, 33,1291−1297..

Hu,J.T.;Huang,Y.;Yao,Y.M.;Pan,G.R.;Sun,J.J.;Zeng,X.L.;Sun,R.;Xu,J.B.;Song,B.;Wong,C.P.Polymercompositewithimprovedthermalconductivitybyconstructingahierarchicallyorderedthree-dimensionalinterconnectednetworkofBN.ACS Appl. Mater. Interfaces2017, 9,13544−13553..

Jung,D.W.;Kim,J.M.;Yoon,H.W.;Nam,K.M.;Kwon,Y.E.;Jeong,S.;Baek,Y.H.;Choi,Y.S.;Chang,S.J.;Yi,G.R.;Cha,J.Y.;Lee,G.Solution-processablethermallyconductivepolymercompositeadhesivesofbenzyl-alcohol-modifiedboronnitridetwo-dimensionalnanoplates.Chem. Eng. J.2019, 361,783−791..

Su,X.;Wang,R.Y.;Li,X.F.;Araby,S.;Kuan,H.C.;Naeem,M.;Ma,J.Acomparativestudyofpolymernanocompositescontainingmulti-walledcarbonnanotubesandgraphenenanoplatelets.Nano Mater. Sci.2022, 4,185−204..

Burger,N.;Laachachi,A.;Ferriol,M.;Lutz,M.;Toniazzo,V.;Ruch,D.Reviewofthermalconductivityincomposites:mechanisms,parametersandtheory.Prog. Polym. Sci.2016, 61,1−28..

Che,J.W.;Cagin,T.;GoddardIII,W.A.Thermalconductivityofcarbonnanotubes.Nanotechnology2000, 11,65..

Han,Z.;Fina,A.Thermalconductivityofcarbonnanotubesandtheirpolymernanocomposites:areview.Prog. Polym. Sci.2011, 36,914−944..

Thostenson,E.T.;Chou,T.W.Processing-structure-multi-functionalpropertyrelationshipincarbonnanotube/epoxycomposites.Carbon2006, 44,3022−3029..

Yuan,S.Q.;Bai,J.M.;Chua,C.K.;Wei,J.;Zhou,K.HighlyenhancedthermalconductivityofthermoplasticnanocompositeswithalowmassfractionofMWCNTsbyafacilitatedlatexapproach.Compos. Part A: Appl. Sci. Manuf.2016, 90,699−710..

Wu,N.;Che,S.;Li,H.W.;Wang,C.N.;Tian,X.J.;Li,Y.F.Areviewofthree-dimensionalgraphenenetworksforuseinthermallyconductivepolymercomposites:constructionandapplications.New Carbon Mater.2021, 36,911−926..

Zhang,F.;Feng,Y.Y.;Feng,W.Three-dimensionalinterconnectednetworksforthermallyconductivepolymercomposites:design,preparation,properties,andmechanismsMater.Sci. Eng. R-Rep.2020, 142,100580..

Liu,P.F.;Li,X.F.;Min,P.;Chang,X.Y.;Shu,C.;Ding,Y.;Yu,Z.Z.3Dlamellar-structuredgrapheneaerogelsforthermalinterfacecompositeswithhighthrough-planethermalconductivityandfracturetoughness.Nano-Micro Lett.2021, 13,1..

Wang,F.Z.;Zhang,S.;Li,X.Q.;Wang,W.;Shi,M.X.;Huang,Z.X.;Li,C.S.Constructionoffunctionalizedgraphenenanoplatelets/SiCnanowireshybridskeletonforepoxycompositeswithenhancedthermalconductivityandthermomechanicalproperties.Mater. Res. Bull.2023, 162,112189..

Eksik,O.;Bartolucci,S.F.;Gupta,T.;Fard,H.;Tasciuc,T.B.;Koratkar,N.Anovelapproachtoenhancethethermalconductivityofepoxynanocompositesusinggraphenecore-shelladditives.Carbon.2016, 101,239−244..

Tao,J.R.;Luo,C.L.;Huang,M.L.;Weng,Y.X.;Wang,M.Constructionofuniqueconductivenetworksincarbonnanotubes/polymercompositesviapoly( ε-caprolactone)inducingpartialaggregationofcarbonnanotubesformicrowaveshieldingenhancement.Compos. Part A: Appl. Sci. Manuf.2023, 164,107304..

Luo,F.B.;Yang,S.G.;Yan,P.P.;Li,H.Z.;Huang,B.Q.;Qian,Q.R.;Chen,Q.H.Orientationbehaviorandthermalconductivityofliquidcrystalpolymercompositesbasedonthree-dimensionalprinting.Compos. Part A Appl. Sci. Manuf.2022, 160,107059..

Min,S.B.;Kim,M.;Hyun,K.;Ahn,C.W.;Kim,C.B.Thermallyconductive2Dfillerorientationcontrolinpolymerusingthermophoresis.Polym. Test.2023, 117,107838..

Yu,S.;Shen,X.;Kim,J.K.Beyondhomogeneousdispersion:orientedconductivefillersforhigh knanocomposites.Mater. Horiz.2021, 8,3009−3042..

Han,J.K.;Du,G.L.;Gao,W.W.;Bai,H.Ananisotropicallyhighthermalconductiveboronnitride/epoxycompositebasedonnacre-mimetic3Dnetwork.Adv. Funct. Mater.2019, 29,1900412..

Jiao,D.J.;Song,N.;Ding,P.;Shi,L.Y.Enhancedthermalconductivityinorientedcellulosenanofibril/graphenecompositesviainterfacialengineering.Compos. Commun.2022, 31,101101..

Mao,L.;Han,J.B.;Zhao,D.;Song,N.;Shi,L.Y.;Wane,J.H.Particlepackingtheoryguidedthermalconductivepolymerpreparationandrelatedproperties.ACS Appl. Mater. Interfaces2018, 10,33556−33563..

Ma,M.;Chu,Q.D.;Lin,H.;Xu,L.;He,H.W.;Shi,Y.Q.;Chen,S.;Wang,X.Highlyanisotropicthermalconductivityandelectricalinsulationofnanofibrillatedcellulose/Al2O3@rGOcompositefilms:effectoftheparticlesize.Nanotechnology2022, 33,135711..

Li,R.;Yang,X.;Li,J.;Shen,Y.;Zhang,L.;Lu,R.;Wang,C.;Zheng,X.;Chen,H.;Zhang,T.Reviewonpolymercompositeswithhighthermalconductivityandlowdielectricpropertiesforelectronicpackaging.Mater. Today Phys.2022, 22,100594..

Hao,M.;Qian,X.;Zhang,Y.G.;Yang,J.M.;Li,C.J.;Gong,H.T.;Wang,X.F.;Wang,P.P.;Liu,L.;Huang,Y.D.Thermalconductivityenhancementofcarbonfiber/epoxycomposites viaconstructingthree-dimensionallyalignedhybridthermalconductivestructuresonfibersurfaces.Compos. Sci. Technol.2023, 231,109800..

Wu,W.F.;Ren,T.L.;Liu,X.Q.;Davis,R.;Huai,K.;Cui,X.;Wei,H.X.;Hu,J.J.;Xia,Y.M.;Huang,S.H.;Qiang,Z.;Fu,K.;Zhang,J.M.;Chen,Y.W.Creatingthermalconductivepathwaysinpolymermatrixbydirectionalassemblyofsynergisticfillersassistedbyelectricfields.Compos. Commun.2022, 35,101309..

Wen,Y.F.;Chen,C.;Ye,Y.S.;Xue,Z.G.;Liu,H.Y.;Zhou,X.P.;Zhang,Y.;Li,D.Q.;Xie,X.L.;Mai,Y.W.Advancesonthermallyconductiveepoxy-basedcompositesaselectronicpackagingunderfillmaterials—areview.Adv. Mater.2022, 34,2201023..

Hu,Z.F.;Zhao,T.T.;Dong,L.J.;Zhang,Y.Polyhedraloligosilsesquioxane-modifiedalumina/aluminumnitride/siliconerubbercompositestoenhancedielectricpropertiesandthermalconductivity.J. Electron. Mater.2022, 51,2308−2315..

Lule,Z.C.;Kim,J.Organic-inorganichybridfillerforimprovedthermalconductivityandanti-drippingperformanceofpolybutylenesuccinatecomposite.J. Clean Prod.2022, 340,130781..

Yu,A.P.;Ramesh,P.;Sun,X.B.;Bekyarova,E.;Itkis,M.E.;Haddon,R.C.Enhancedthermalconductivityinahybridgraphitenanoplatelet-carbonnanotubefillerforepoxycomposites.Adv. Mater.2008, 20,4740−4744..

Niu,N.T.;Zhang,Y.;Xiao,G.;He,X.H.;Yao,Y.G.Preparationofquasi-isotropicthermalconductivecompositesbyinterconnectingsphericalaluminaand2Dboronnitrideflakes.Rare Metals2023, 42,1283−1293..

Zhang,X.;Song,J.A.;Meng,J.J.;Zhang,K.AnisotropicPDMS/alumina/carbonfibercompositeswithahighthermalconductivityandanelectromagneticinterferenceshieldingperformance.Materials2022, 15,8078..

Kashfipour,M.A.;Guo,M.L.;Mu,L.W.;Mehra,N.;Cheng,Z.H.;Olivio,J.;Zhu,S.S.;Maia,J.M.;Zhu,J.H.Carbonnanofiberreinforcedco-continuousHDPE/PMMAcomposites:exploringtheroleofviscosityratioonfillerdistributionandelectrical/thermalproperties.Compos. Sci. Technol.2019, 184,107859..

Huang,Y.;Ellingford,C.;Bowen,C.;McNally,T.;Wu,D.M.;Wan,C.Y.Tailoringtheelectricalandthermalconductivityofmulti-componentandmulti-phasepolymercomposites.Int. Mater. Rev.2020, 65,129−163..

Wu,W.J.;Liu,H.W.;Wang,Z.Y.;Lv,P.;Hu,E.T.;Zheng,J.J.;Yu,K.H.;Wei,W.Formationofthermalconductivenetworkinboronnitride/polyvinylalcoholbyice-templatedself-assembly.Ceram. Int.2021, 47,33926−33929..

Chen,X.L.;Lim,J.S.K.;Yan,W.L.;Guo,F.;Liang,Y.N.;Chen,H.;Lambourne,A.;Hu,X.SalttemplateassistedBNscaffoldfabricationtowardhighlythermallyconductiveepoxycomposites.ACS Appl. Mater. Interfaces2020, 12,16987−16996..

Yang,W.;Wang,Y.F.;Li,Y.;Gao,C.;Tian,X.J.;Wu,N.;Geng,Z.S.;Che,S.;Yang,F.;Li,Y.F.Three-dimensionalskeletonassembledbycarbonnanotubes/boronnitrideasfillerinepoxyforthermalmanagementmaterialswithhighthermalconductivityandelectricalinsulation.Compos. Part B Eng.2021, 224,109168..

Xu,X.W.;Hu,R.C.;Chen,M.Y.;Dong,J.F.;Xiao,B.;Wang,Q.;Wang,H.3Dboronnitridefoamfilledepoxycompositeswithsignificantlyenhancedthermalconductivitybyafacialandscalableapproach.Chem. Eng. J.2020, 397,125447..

Fu,H.B.;Huang,Y.;Liu,Y.;Li,F.;Gai,Z.P.;Jiang,Y.;Gao,X.L.;Zhuang,J.;Sun,J.Y.;Xu,H.;Wu.D.M.Enhancedthermalconductionofhybridfiller/polydimethylsiloxanecomposites viaacontinuousspatialconfiningprocess.Compos. Sci. Technol.2022, 226,109536..

Sumita,M.;Sakata,K.;Asai,S.;Miyasaka,K.;Nakagawa,H.Dispersionoffillersandtheelectricalconductivityofpolymerblendsfilledwithcarbonblack.Polym. Bull.1991, 25,265−271..

Li,T.T.;Wang,Y.X.;Wang,Y.T.;Sun,F.;Xu,J.W.;Lou,C.W.;Lin,J.H.Preparationofflexible,highlyconductivepolymercompositefilmsbasedondoublepercolationstructuresandsynergisticdispersioneffect.Polym. Compos.2021, 42,5159−5167..

Cao,J.P.;Zhao,X.D.;You,F.;Yu,H.Z.;Hu,G.H.;Dang,Z.M.Highthermalconductivityandhighelectricalresistivityofpoly(vinylidenefluoride)/polystyreneblendsbycontrollingthelocalizationofhybridfillers.Compos. Sci. Technol.2013, 89,142−148..

Yang,L.;Zheng,Y.;Hou,M.;Chen,W.Y.;Wang,Z.Q.Constructingofhighlyordered3Dnetworkofcarbonnanotubeinsidepolymermatrixandtheimprovementsinpropertiesofthecomposites.Am. J. Polym. Sci. Technol.2019, 5,9−15..

Li,M.D.;Wang,Y.X.;Wang,Y.T.;Sun,F.;Xu,J.W.;Lou,C.W.;Lin,J.H.Thermalmanagementofchipsbyadeviceprototypeusingsynergisticeffectsof3-Dheat-conductivenetworkandelectrocaloricrefrigeration.Nat. Commun.2022, 13,5849..

Wang,J.Q.;Hu,L.;Li,W.H.;Ouyang,Y.G.;Bai,L.Y.Developmentandperspectivesofthermalconductivepolymercomposites.Nanomaterials2022, 12,3574..

浏览量

Downloads

CSCD

文章被引用时，请邮件提醒。

Submit

工具集

关联资源

Simultaneously Improved Dielectric Constant and Breakdown Strength of PVDF-based Composites with Polypyrrole Nanowire Encapsuled Molybdenum Disulfide Nanosheets

Polyarylene Ether Nitrile and Titanium Dioxide Hybrids as Thermal Resistant Dielectrics

OPTICAL BAND GAP AND CONDUCTIVITY MEASUREMENTS OF POLYPYRROLE-CHITOSAN COMPOSITE THIN FILMS