연구동향 분석
박사

Study on high performance polyamide 66 composites with improved interfacial affinity via plasma-assisted mechanochemistry

유지완 2020년

논문상세정보
인용/피인용
' Study on high performance polyamide 66 composites with improved interfacial affinity via plasma-assisted mechanochemistry' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • Carbon fiber-reinforced thermoplastics
  • Interfacial affinity/adhesion
  • Mechanical properties
  • Thermal conductivity
  • mechanochemistry
  • plasma
  • polymer composites
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
684 0

0.0%

' Study on high performance polyamide 66 composites with improved interfacial affinity via plasma-assisted mechanochemistry' 의 참고문헌

  • thermal and interfacial performances of carbon fiber reinforced composites flavored by carbon nanotube in matrix/interface
    159 (761-772 [2017]
  • i. mechanism of plasticizing by cold mastication
    9 ( [1952]
  • highly photoluminescent carbon dots from ammonium citrate
    6 ( [2014]
  • chemical verification of the mechanical degradation mechanism of cold mastication
    19 ( [1956]
  • [4] M. Sharma, S. Gao, E. Mader, H. Sharma, L.Y. Wei, J. Bijwe,Carbon fiber surfaces andComposite interphases,Compos. Sci. Technol. 102 (2014) 35-50.
    102 ( [2014]
  • [49] Morishita T, Okamoto H. Facile exfoliation and noncovalent superacid functionalization of boron nitride nanosheets and their use for highly thermally conductive and electrically insulating polymer nanocomposites. ACS Appl Mater Interfaces. 2016;8(40):27064-73.
  • [37] S. Lei, X. Wang, B. Li, J. Kang, Y. He, A. George, L. Ge, Y. Gong, P. Dong, Z. Jin, G. Brunetto, W. Chen, Z.-T. Lin, R. Baines, D.S. Galvao, J. Lou, E. Barrera, K. Banerjee, R. Vajtai, P. Ajayan, Surface functionalization of twodimensional metal chalcogenides by Lewis acid?base chemistry, Nat. Nanotechnol. 11 (2016) 465-471.
  • [35] J.E. McMurry, OranicChemistry, seventh ed.,Cengage Learning 2008.
    [2008]
  • [35] G. Gao, W. Gao, E.Cannuccia, J. Taha-Tijerina, L. Balicas, A. Mathkar, T.N. Narayanan, Z. Liu, B.K. Gupta, J. Peng, Y. Yin, A. Rubio, P.M. Ajayan, Artificially stacked atomic layers: toward new van der waals solids, Nano Lett. 12 (2012) 3518-3525.
    12 ( [2012]
  • [35] D. Hegemann, H. Brunner,C. Oehr, Plasma treatment of polymers to generate stable, hydrophobic surfaces, Plasmas Polym. 6 (2001) 221-235.
    6 ( [2001]
  • [32] Boldyreva E. Mechanochemistry of inorganic and organic systems: what is similar, what is different? Chem Soc Rev. 2013;42:7719-38.
  • [2] H.W. Zhou, L. Mishnaevsky, H.Y. Yi, Y.Q. Liu, X. Hu, A. Warrier, G.M. Dai,Carbon fiber/carbon nanotube reinforced hierarchicalComposites: Effect ofCNT distribution on shearing strength,Composites, Part B 88 (2016) 201-211.
    88 ( [2016]
  • [28] N. Vasanthan, Crystallinity determination of nylon 66 by density measurement and fourier transform infrared (FTIR) spectroscopy, J. Chem. Educ. 89 (2012) 387-390.
  • [27] W. Kauzmann, H. Eyring, The viscous rlow of large molecules, J. Am. Chem. Soc. 62 (1940) 3113-3125.
  • [24] HOSOKAWA ALPINE Aktiengesellschaft, 2016. https://www.hosokawaalpine.com/.
  • [23] J. Frenkel, Orientation and rupture of linear macromolecules in dilute solutions under the influence of viscous flow, Acta Physicochim. URSS 19 (1944) 51-76.
  • [22] Z. JUHZSZ, Mechanochemische erscheinungen beim feinmahlen von tonmineralen, Sprechsaal 118 (1985) 110-119.
  • [20] Y. Hernandez, V. Nicolosi, M. Lotya, F.M. Blighe, Z. Sun, S. De, I.T. McGovern, B. Holland, M. Byrne, Y.K. Gun'Ko, J.J. Boland, P. Niraj, G. Duesberg, S. Krishnamurthy, R. Goodhue, J. Hutchison, V. Scardaci, A.C. Ferrari, J.N. Coleman, High-yield production of graphene by liquid-phase exfoliation of graphite, Nat. Nanotechnol. 3 (2008) 563?568.
  • [1] A.D. Kraus, A. Bar-Cohen, Design and analysis of heat sinks, J. Wiley 1995.
  • [18] V.V. Boldyrev, Mechanochemistry and mechanical activation of solids, Russ.Chem. Rev. 75 (2006) 177.
    75 ( [2006]
  • [17] A. Smekal, Ritzvorgang und molekulare Festigkeit, Naturwissenschaften 30 (1942) 224-225.
  • [16] J.J. Gilman, Mechanochemistry, Science 274 (1996) 65-65.
  • [13] J.A. Manson, Polymer blends andComposites, Springer Science Business Media, Springer, 2012.
    [2012]
  • [12] L.H. Sharpe, The interphase in adhesion, J. Adhes 4 (1972) 51-64.
  • Zhang H. The chemistry of two-dimensional layered transition metal dichalcogenide nanosheets
    5:263-75 [2013]
  • Yu S-H. Scalable template synthesis of resorcinol ? formaldehyde/graphene oxide composite aerogels with tunable densities and mechanical properties
    54 ( 8 ) :2397-401 [2015]
  • Y. Boron nitride colloidal solutions , ultralight aerogels and freestanding membranes through one-step exfoliation and functionalization
    6.395138889 [2015]
  • X. Functional three-dimensional graphene/polymer composites
    10 ( 8 ) :7231-47 . [2016]
  • Wong C-P. Construction of 3D skeleton for polymer composites achieving a high thermal conductivity
    14 ( 13 ) :1704044 [2018]
  • Wong C-P. A A Combination of boron nitride nanotubes and cellulose nanofibers for the preparation of a nanocomposite with high thermal conductivity
    11 ( 5 ) :5167- 78 [2017]
  • Wang Y. B-doped carbon coating improves the electrochemical performance of electrode materials for Li-ion batteries
    24 ( 35 ) :5511-21 . [2014]
  • W. Melt blending in situ enhances the interaction between polystyrene and graphene through ¥ð ? ¥ð stacking .
    3 ( 8 ) :3103-9 . [2011]
  • Unmodified and modified surface sisal fibers as reinforcement of phenolic and lignophenolic matrices composites : thermal analyses of fibers and composites
    291 ( [2006]
  • Uncovering the pKa dependent fluorescence quenching of carbon dots induced by chlorophenols
    7 ( [2015]
  • Ultrathin flexible reduced graphene oxide/cellulose nanofiber composite films with strongly anisotropic thermal conductivity and efficient electromagnetic interference shielding ,
    5 ( [2017]
  • Toward highly thermally conductive all-carbon composites : structure control
    109 ( [2016]
  • Toughening of Carbon Fiber-Reinforced Epoxy Polymer Composites Utilizing Fiber Surface Treatment and Sizing .
    90 ( [2016]
  • Thermally conductive graphene-polymer composites : size , percolation , and synergy effects
    27 ( [2015]
  • Thermally conductive composite films of hexagonal boron nitride and polyimide with affinity-enhanced interfaces
    20:2749-52 [2010]
  • Thermal exfoliation of hexagonal boron nitride for effective enhancements on thermal stability , flame retardancy and smoke suppression of epoxy resin nanocomposites via sol ? gel process
    4 ( 19 ) :7330-40 [2016]
  • Thermal design : heat sinks , thermoelectrics , heat pipes , compact heat exchangers , and solar cells
    [2010]
  • Thermal conductivity of polymer composites with the geometrical characteristics of graphene nanoplatelets
    6:26825 [2016]
  • Thermal conductivity of a graphene oxide ? carbon nanotube hybrid/epoxy Composite
    50 ( [2012]
  • Thermal conductivity and structure of noncovalent functionalized graphene/epoxy Composites
    49 ( [2011]
  • Thermal and dynamic mechanical characterization of polypropylene-woodflour composites
    42 ( [2002]
  • The surface analytical characterization of carbon fibers functionalized by H2SO4/HNO3 treatment
    46 ( [2008]
  • The reinforcement mechanism of fiber-glass reinforced plastics under wet conditions : A review
    18 ( [1978]
  • The effect of amino-silane coupling agents having different molecular structures on the mechanical properties of basalt fiber-reinforced polyamide 6,6 composites
    163 ( [2019]
  • The cutting of multi-walled carbon nanotubes and their strong interfacial interaction with polyamide 6 in the solid state
    44 ( [2006]
  • T. Supramolecular concepts and new techniques in mechanochemistry : cocrystals , cages , rotaxanes , open metal ? organic frameworks
    41:3493-510 [2012]
  • Synthesis of engineered particulates with tailored properties using dry particle coating
    117 ( [2001]
  • Synthesis of N-doped graphene by chemical vapor deposition and its electrical properties
    9 ( [2009]
  • Synthesis and characterization of a new hierarchical reinforcement by chemically grafting graphene oxide onto carbon fibers
    22 ( [2012]
  • Synthesis , structure , mechanical properties , and thermal stability of some polysulfone/organoclay nanocomposites
    42 ( [2001]
  • Synergistic toughening of graphene oxide ? molybdenum disulfide ? thermoplastic polyurethane ternary artificial nacre
    9 ( [2015]
  • Surface modification of ultrafiltration membranes by low temperature plasma II . Graft polymerization onto polyacrylonitrile and polysulfone
    111 ( [1996]
  • Surface modification of polymers for medical applications
    15 ( [1994]
  • Surface functionalization of nanoparticles with polyethylene glycol : effects on protein adsorption and cellular uptake ,
    9 ( [2015]
  • Supramolecular concepts and new techniques in mechanochemistry : cocrystals , cages , rotaxanes , open metal ? organic frameworks
    41 ( [2012]
  • Structure and properties of poly ( vinyl alcohol ) /na+ montmorillonite nanocomposites
    12 ( [2000]
  • Solvent-free mechanochemical reduction of graphene oxide
    77 ( [2014]
  • Single-layer graphene nanosheets withControlled grafting of polymerChains
    20 ( [2010]
  • Simultaneous surface functionalization and reduction of graphene oxide with octadecylamine for electricallyConductive polystyreneComposites ,
    49 ( [2011]
  • Significant enhancement of thermalConductivity in bioinspired freestanding boron nitride papers filled with graphene oxide
    28 ( 4 ) :1049-57 . [2016]
  • Shimizu H. Ultrahigh-shear processing for the preparation of polymer/carbon nanotubeComposites
    45 ( 12 ) :2334-40 . [2007]
  • Shigehara K. Flame resistant nylon-6,6Composites with improved mechanical strength by theCombination of additiveand reactive-type flame retardants
    39:347-58 [2007]
  • S/A, “Vieques: Viequenses. La Isla Nena”, en Nuestro Puerto Rico, http://nuestropuertorico.com/municipalities/en-vieques/ [consulta: 25 marzo 2019].
  • Role of thermal boundary resistance on the heat flow inCarbon-nanotubeComposites
    95 ( [2004]
  • Recent advances in graphene based polymerComposites
    35 ( 11 ) :1350-75 . [2010]
  • Principles of plasma discharges and materials processing
    [2005]
  • Preparation ofCovalently functionalized graphene using residual oxygen-containing functional groups
    2 ( [2010]
  • Preparation of functionalized graphene by simultaneous reduction and surface modification and its polymethyl methacrylateComposites through latex technology and melt blending
    226 ( 15 ) :326-35 . [2013]
  • Preparation ,Characterization , and electrochromic properties of nanocellulose-based polyaniline nanocomposite films
    9 ( [2017]
  • Plasmaassisted mechanochemistry to produce polyamide/boron nitride nanocomposites with high thermalConductivities and mechanical properties
    164 ( [2019]
  • Plasma treatment of polymers for surface and adhesion improvement , Nuclear Instruments and Methods in Physics Research Section B : Beam Interactions with Materials and Atoms 208
    [2003]
  • Plasma functionalization of multiwalledCarbon nanotubes and their use in the preparation of nylon 6-based nanohybrids
    9 ( [2012]
  • Physics of radio-frequency plasmas (
    [2011]
  • Photolatent baseCatalyzed michael-addition andConcomitant in situ graphene oxide reduction to obtain electrically and thermallyConductive UV-curedComposite ,
    108 ( [2017]
  • Oxygen radical functionalization of boron nitride nanosheets .
    134 ( 45 ) :18758-71 . [2012]
  • On the lack of thermal percolation in carbon nanotube composites
    87 ( [2005]
  • Nutt S. Single-layer graphene nanosheets with controlled grafting of polymer chains
    20:1982-92 [2010]
  • Nutt S. Covalent polymer functionalization of graphene nanosheets and mechanical properties of composites
    19:7098-105 [2009]
  • Nitrogen-doped , carbonrich , highly photoluminescent carbon dots from ammonium citrate
    6:1890-5 [2014]
  • N.M. Pugno , R. Adelung , Hierarchical self-entangled carbon nanotube tube networks
    8 ( [2017]
  • Morphology and properties of thermoplastic polyurethane nanocomposites incorporating hydrophilic layered silicates
    45 ( [2004]
  • Mechanochemistry of solids : past , present , and prospects
    8 ( [2000]
  • Mechanochemistry of inorganic and organic systems : what is similar , what is different ?
    42 ( [2013]
  • Mechanochemistry : the mechanical activation of covalent bonds
    105 ( [2005]
  • Mechanochemical reactions of OH-containing crystals
    130 ( [1993]
  • Mechanochemical degradation in transient elongational flowMacromolecules : Synthesis , Order and Advanced Properties
    pp . 73-182
  • Mechanochemical activation of silicate minerals by dry fine grinding
    10 ( [1974]
  • Mechanism of clay tactoid exfoliation in epoxy-clay nanocomposites
    7 ( [1995]
  • Mechanical properties and fracture behaviour of multilayer alumina composites
    30 ( [2015]
  • Mechanical and thermal behaviours of graphite flake-reinforced acrylonitrile ? butadiene ? styrene composites and their correlation with entanglement density
    6 ( [2016]
  • Magnetic alignment of hexagonal boron nitride platelets in polymer matrix : toward high performance anisotropic polymer composites for electronic encapsulation
    5 ( 15 ) :7633-40 [2013]
  • Lu C. Mechanochemical preparation of surface-acetylated cellulose powder to enhance mechanical properties of cellulose-filler-reinforced NR vulcanizates
    68 ( 12 ) :2479-84 . [2008]
  • Layer-by-layer grafting CNTs onto carbon fibers surface for enhancing the interfacial properties of epoxy resin composites
    154 ( [2018]
  • Largely improved thermal conductivity of HDPE/expanded graphite/carbon nanotubes ternary composites via filler network-network synergy
    99 (32-40 . [2017]
  • Khil M-S. Volume control of expanded graphite based on inductively coupled plasma and enhanced thermal conductivity of epoxy composite by formation of the filler network
    119:40-6 [2017]
  • Jiang P. Cellulose nanofiber supported 3D interconnected BN nanosheets for epoxy nanocomposites with ultrahigh thermal management capability
    27 ( 5 ) :1604754-62 [2017]
  • Introduction of an enhanced binding of reduced graphene oxide to polyurethane sponge for oil absorption ,
    54 ( [2015]
  • Interphases in graphene polymer-based nanocomposites : achievements and challenges
    23 ( [2011]
  • Interfacially reinforced carbon fiber composites by grafting modified methylsilicone resin
    140 ( [2017]
  • Interfacial modification and enhancement of toughening mechanisms in epoxy composites with CNTs grafted on carbon fibers
    134 ( [2016]
  • Interfacial microstructure and properties of carbon fiber composites modified with graphene oxide
    4 ( 3 ) ( [2012]
  • Interfacial improvement of carbon fiber/epoxy composites using a simple process for depositing commercially functionalized carbon nanotubes on the fibers
    52 ( [2013]
  • Interface Enhancement of Carbon Fiber Reinforced Methylphenylsilicone Resin Composites Modified with Silanized Carbon Nanotubes
    89 ( [2016]
  • Interactions of non-thermal atmospheric pressure plasma with solid and liquid food systems : a review
    7 ( [2015]
  • Infrared characteristic group frequencies : tables and charts , 2nd ed.
    [1994]
  • Infrared and Raman characteristic group frequencies : tables and charts
    [2004]
  • In situ intercalation polymerization approach to polyamide-6/graphite nanoflakes for enhanced thermal conductivity
    117 (165-173 . [2017]
  • Improving the interfacial properties of carbon fiber-reinforced epoxy composites by grafting of branched polyethyleneimine on carbon fiber surface in supercritical methanol
    114 ( [2015]
  • Improved thermal conductivity for chemically functionalized exfoliated graphite/epoxy composites
    46 ( [2008]
  • Improved strength and toughness of semi-aromatic polyamide 6T-co6 ( PA6T/6 ) /GO composites via in situ polymerization
    175 ( [2019]
  • Implication of controlled embedment of graphite nanoplatelets assisted by mechanochemical treatment for electro-conductive polyketone composite
    66 ( [2018]
  • Hydration and dynamic state of nanoconfined polymer layers govern toughness in nacre-mimetic nanocomposites
    25 ( [2013]
  • Hot-pressing induced alignment of boron nitride in polyurethane for composite films with thermal conductivity over 50 ? Wm ? 1 ? K ? 1
    160 ( 26 ) :199-207 . [2018]
  • Highperformance polyketone nanocomposites achieved via plasma-assisted mechanochemistry
    183 ( [2019]
  • Highly thermally conductive and mechanically robust polyamide/graphite nanoplatelet composites via mechanochemical bonding techniques with plasma treatment
    160 ( [2018]
  • Highly thermal conductive composites with polyamide-6 covalently-grafted graphene by an in situ polymerization and thermal reduction process
    66 ( [2014]
  • Highly improved interfacial affinity in carbon fiber-reinforced polymer composites via oxygen and nitrogen plasma-assisted mechanochemistry ,
    165 (725-732 . [2019]
  • Highly enhanced crystallization kinetics of poly ( l-lactic acid ) by poly ( ethylene glycol ) grafted graphene oxide simultaneously as heterogeneous nucleation agent and chain mobility promoter
    48 ( 14 ) :4891-900 . [2015]
  • High interlaminar shear strength enhancement of carbon fiber/epoxy composite through fiber- and matrix-anchored carbon nanotube networks ,
    9 ( [2017]
  • High electrothermal performance of expanded graphite nanoplatelet-based patch heater
    22 ( [2012]
  • Hierarchical composites reinforced with carbon nanotube grafted fibers : the potential assessed at the single fiber level
    20 ( [2008]
  • Graphite Nanoplatelet-Epoxy Composite Thermal Interface Materials
    C 111 ( [2007]
  • Graphene-based thermoplastic composites and their application for LED thermal management
    102 ( [2016]
  • Graphene-based composite materials
    442:282-6 [2006]
  • Graphene ? multilayer graphene nanocomposites as highly efficient thermal interface materials
    12 ( [2012]
  • Golberg D. Nano boron nitride flatland
    43:934-59 [2014]
  • Golberg D. Functionalized hexagonal boron nitride nanomaterials : emerging properties and applications
    45:3989-4012 [2016]
  • Functionalized graphene sheets for polymer nanocomposites
    3:327-31 [2008]
  • Free-radicalinduced grafting from plasma polymer surfaces
    116 ( [2016]
  • Fracture toughness and water uptake of highperformance epoxy/nanoclay nanocomposites
    65 ( [2005]
  • Force-induced activation of covalent bonds in mechanoresponsive polymeric materials
    459 ( [2009]
  • Flow-induced chain fracture of isolated linear macromolecules in solution
    24 ( [1986]
  • Flexible polyimide films hybrid with functionalized boron nitride and graphene oxide simultaneously to improve thermal conduction and dimensional stability .
    6 ( 11 ) :8639-45 [2014]
  • Flame resistant nylon-6,6 composites with improved mechanical strength by the combination of additiveand reactive-type flame retardants
    39 ( [2007]
  • First principles dynamics and minimum energy pathways for mechanochemical ring opening of cyclobutene .
    131 ( [2009]
  • Feng L. Uncovering the pKa dependent fluorescence quenching of carbon dots induced by chlorophenols
    7:6348-55 [2015]
  • Fabrication of robust and highly thermally conductive nanofibrillated cellulose/graphite nanoplatelets composite papers
    138 ( [2017]
  • Excellent mechanical properties of long multiwalled carbon nanotube bridged Kevlar fabric
    137 ( [2018]
  • Enhanced thermal conductivity of epoxy ? graphene composites by using non-oxidized graphene flakes with non-covalent functionalization
    25 ( [2013]
  • Enhanced thermal conductivity in a hybrid graphite nanoplatelet ? carbon nanotube filler for epoxy composites
    20 ( [2008]
  • Enhanced thermal conductivity and mechanical property through boron nitride hot string in polyvinylidene fluoride fibers by electrospinning
    156 ( 1 ) :1-7 . [2018]
  • Enhanced mechanical properties of epoxy nanocomposites by mixing noncovalently functionalized boron nitride nanoflakes
    9 ( 15 ) :2602-10 . [2013]
  • Enhanced interphase between epoxy matrix and carbon fiber with carbon nanotube-modified silane coating
    99 ( [2014]
  • Enhanced interfacial and mechanical properties of high-modulus carbon fiber composites : Establishing modulus intermediate layer between fiber and matrix based on tailored-modulus epoxy
    163 ( [2018]
  • Effects of solvent viscosity on polystyrene degradation in transient elongational flow
    23 ( [1990]
  • Effects of silanization and silica enrichment of carbon fibers on interfacial properties of methylphenylsilicone resin composites
    98 (159-165 . [2017]
  • Effects of bonding types of carbon fibers with branched polyethyleneimine on the interfacial microstructure and mechanical properties of carbon fiber/epoxy resin composites
    117 ( [2015]
  • Effects of Degree Of Chemical Interaction between Carbon Fibers and Surface Sizing on Interfacial Properties of Epoxy Composites
    163 ( [2018]
  • Effect of morphology and defectiveness of graphene-related materials on the electrical and thermal conductivity of their polymer nanocomposites
    102 ( [2016]
  • Effect of functionalizedCarbon nanotubes on the thermalConductivity of epoxyComposites
    48 ( [2010]
  • Effect of ammonium-salt solutions on the surface properties of carbon fibers in electrochemical anodic oxidation
    259 ( [2012]
  • Dynamic mechanical properties of multiwall carbon nanotube reinforced ABS composites and their correlation with entanglement density
    6 ( [2016]
  • Dyeing mechanism and optimization of polyamide 6,6 functionalized with double barrier discharge ( DBD ) plasma in air
    293 ( [2014]
  • Dubois P. Free-radical-induced grafting from plasma polymer surfaces
    116 ( 6 ) :3975-4005 . [2016]
  • Dielectric thermally conductive boron nitride/polyimide composites with outstanding thermal stabilities via in-situ polymerization-electrospinning-hot press method
    94:209-16 [2017]
  • Dibromocarbene functionalization of boron nitride nanosheets : toward band gap manipulation and nanocomposite applications
    26 ( 24 ) :7039-50 . [2014]
  • Design and fabrication of morphologically controlled carbon nanotube/polyamide-6based composites as electrically insulating materials having enhanced thermal conductivity and elastic modulus
    142 ( [2017]
  • Dense graphene foam and hexagonal boron nitride filled PDMS composites with high thermal conductivity and breakdown strength
    152 ( 10 ) :243-53 [2017]
  • Covalent polymer functionalization of graphene nanosheets and mechanical properties of composites
    19 ( [2009]
  • Copolymers based on telechelic benzoxazine with a reactive main-chain and anhydride : monomer and polymer synthesis , and thermal and mechanical properties of carbon fiber composites
    5 ( [2015]
  • Cold plasma in materials fabrication
    [1994]
  • Clausen-Schaumann H. Mechanochemistry : the mechanical activation of covalent bonds
    105 ( 8 ) :2921-48 . [2005]
  • Cellulose nanofiber supported 3D interconnected BN nanosheets for epoxy nanocomposites with ultrahigh thermal management capability
    27 ( [2017]
  • Catalyst-free synthesis of nitrogen-doped graphene via thermal annealing graphite oxide with melamine and its excellent electrocatalysis
    5 ( [2011]
  • Carbon science in 2016 : status , challenges and perspectives
    98 ( [2016]
  • Carbon nanosheets for polymeric nanocomposites with high thermal conductivity
    21 ( [2009]
  • Breaking through the solid/liquid processability barrier : thermal conductivity and rheology in hybrid graphene ?
    9 ( [2017]
  • Bittencourt , Fundamentals of plasma physics
    [2013]
  • Atomic mechanism of fracture of solid polymers
    B 12 ( [1974]
  • Artificially stacked atomic layers : toward new van der Waals solids
    12 ( 7 ) :3518-25 . [2012]
  • Artificial nacre-like papers based on noncovalent functionalized boron nitride nanosheets with excellent mechanical and thermally conductive properties
    7 ( [2015]
  • Application of dynamic mechanical analysis for the study of the interfacial region in carbon fiber/epoxy composite materials
    14 ( [1993]
  • All-organic superhydrophobic coatings with mechanochemical robustness and liquid impalement resistance
    17:355-60 [2018]
  • A review of metal foam and metal matrix composites for heat exchangers and heat Sinks
    33 ( [2012]
  • A high efficient method for introducing reactive amines onto carbon fiber surfaces using hexachlorocyclophosphazene as a new coupling agent
    320 ( [2014]
  • A facile method to prepare flexible boron nitride/poly ( vinyl alcohol ) composites with enhanced thermal conductivity
    149 ( 8 ) :41-7 . [2017]
  • 4.09 Plasma Polymer Deposition and Coatings on Polymers
    4 ( [2014]