Supercritical carbon dioxide assisted phase coarsening of double-percolated polycaprolactone/polystyrene/multi-wall carbon nanotube composites for improved electrical performance and electromagnetic interference shielding
暂无分享,去创建一个
X. Liao | Fangfang Zou | Shaozhe Shi | C. Lv | Fumin Guo | Xiaohan Wang | Guang-xian Li
[1] Kun Zhou,et al. Controlled Distributed Ti3C2Tx Hollow Microspheres on Thermally Conductive Polyimide Composite Films for Excellent Electromagnetic Interference Shielding , 2023, Advanced materials.
[2] Chenghao Luo,et al. Sustainable electromagnetic shielding graphene/nanocellulose thin films with excellent joule heating and mechanical properties via in-situ mechanical exfoliation and crosslinking with cations , 2023, Composites Science and Technology.
[3] Ming Wang,et al. A comparative study on nanoparticle network‐dependent electrical conductivity, electromagnetic wave shielding effectiveness and rheological properties in multiwall carbon nanotubes filled polymer nanocomposites , 2022, Polymer Composites.
[4] Chenghao Luo,et al. Construction of Unique Conductive Networks in Carbon Nanotubes/Polymer Composites via Poly(ε-caprolactone) Inducing Partial Aggregation of Carbon Nanotubes for Microwave Shielding Enhancement , 2022, Composites Part A: Applied Science and Manufacturing.
[5] Guangxian Li,et al. Enhancement of electrical conductivity and electromagnetic interference shielding performance via supercritical CO_2 induced phase coarsening for double percolated polymer blends , 2022, Nano Research.
[6] Sui-lin Liu,et al. Frequency-adjustable electromagnetic interference shielding performance of sandwich-structured conductive polymer composites by selective foaming and tunable filler dispersion , 2022, Composites Communications.
[7] Ming Wang,et al. Migration mechanism of carbon nanotubes and matching viscosity-dependent morphology in Co-continuous Poly(lactic acid)/Poly(ε-caprolactone) blend: Towards electromagnetic shielding enhancement , 2022, Polymer.
[8] Sui-lin Liu,et al. Fabrication of lightweight flexible thermoplastic polyurethane/multiwalled carbon nanotubes composite foams for adjustable frequency-selective electromagnetic interference shielding by supercritical carbon dioxide , 2022, The Journal of Supercritical Fluids.
[9] P. Show,et al. Future advances and challenges of nanomaterial-based technologies for electromagnetic interference-based technologies: A review. , 2021, Environmental research.
[10] Hezhi He,et al. Morphology evolution to form double percolation polylactide/polycaprolactone/MWCNTs nanocomposites with ultralow percolation threshold and excellent EMI shielding , 2021 .
[11] Guangxian Li,et al. Efficient electrical conductivity and electromagnetic interference shielding performance of double percolated polymer composite foams by phase coarsening in supercritical CO2 , 2021 .
[12] Junwei Gu,et al. Structural Design Strategies of Polymer Matrix Composites for Electromagnetic Interference Shielding: A Review , 2021, Nano-Micro Letters.
[13] Jun Lei,et al. Flexible Poly(vinylidene fluoride)-MXene/Silver Nanowire Electromagnetic Shielding Films with Joule Heating Performance , 2021, Industrial & Engineering Chemistry Research.
[14] Shaoyun Guo,et al. Construction, mechanism and prospective of conductive polymer composites with multiple interfaces for electromagnetic interference shielding: A review , 2021, Carbon.
[15] U. Sundararaj,et al. Interface Bridging of Multiwalled Carbon Nanotubes in Polylactic Acid/Poly(butylene adipate-co-terephthalate): Morphology, Rheology, and Electrical Conductivity , 2020 .
[16] Ashutosh Thakur,et al. Cooperative influences of nanoparticle localization and phase coarsening on thermal conductivity of polypropylene/polyolefin elastomer blends , 2019, Composites Part A: Applied Science and Manufacturing.
[17] X. Liao,et al. Organic solvent free preparation of porous scaffolds based on the phase morphology control using supercritical CO2 , 2019, The Journal of Supercritical Fluids.
[18] C. Bowen,et al. Electrical dual-percolation in MWCNTs/SBS/PVDF based thermoplastic elastomer (TPE) composites and the effect of mechanical stretching , 2019, European Polymer Journal.
[19] Na Lu,et al. Electromagnetic Interference Shielding Polymers and Nanocomposites - A Review , 2019, Polymer Reviews.
[20] Xihua Cui,et al. Thermal annealing induced enhancement of electrical properties of a co-continuous polymer blend filled with carbon nanotubes , 2018, Composites Science and Technology.
[21] Guangxian Li,et al. The effects of molecular weight and supercritical CO2 on the phase morphology of organic solvent free porous scaffolds , 2018, The Journal of Supercritical Fluids.
[22] M. R. Aghjeh,et al. Conductive poly(vinylidene fluoride)/polyethylene/graphene blend‐nanocomposites: Relationship between rheology, morphology, and electrical conductivity , 2018 .
[23] Wei Liu,et al. Constructing a double-percolated conductive network in a carbon nanotube/polymer-based flexible semiconducting composite , 2018 .
[24] Guangxian Li,et al. A novel route to the generation of porous scaffold based on the phase morphology control of co-continuous poly(ε-caprolactone)/polylactide blend in supercritical CO2 , 2017 .
[25] U. Sundararaj,et al. Carbon nanotube induced double percolation in polymer blends: Morphology, rheology and broadband dielectric properties , 2017 .
[26] Q. Fu,et al. Achieving a low electrical percolation threshold and superior mechanical performance in poly(L-lactide)/thermoplastic polyurethane/carbon nanotubes composites via tailoring phase morphology with the aid of stereocomplex crystallites , 2017 .
[27] D. Schubert,et al. Enhancing the electrical conductivity of carbon black-filled immiscible polymer blends by tuning the morphology , 2016 .
[28] Q. Zheng,et al. Effect of multi-walled carbon nanotubes on the morphology evolution, conductivity and rheological behaviors of poly(methyl methacrylate)/poly(styrene-co-acrylonitrile) blends during isothermal annealing , 2016 .
[29] R. Cardinaels,et al. Enhancing the conductivity of carbon nanotube filled blends by tuning their phase separated morphology with a copolymer , 2015 .
[30] Dujing Wang,et al. Characterization on the phase separation behavior of styrene-butadiene rubber/polyisoprene/organoclay ternary blends under oscillatory shear. , 2015, The Journal of chemical physics.
[31] S. Howdle,et al. High-pressure rheological analysis of CO2-induced melting point depression and viscosity reduction of poly(ε-caprolactone) , 2015 .
[32] P. Cassagnau,et al. Structuration, selective dispersion and compatibilizing effect of (nano)fillers in polymer blends , 2014 .
[33] Jinrui Huang,et al. Control of carbon nanotubes at the interface of a co-continuous immiscible polymer blend to fabricate conductive composites with ultralow percolation thresholds , 2014 .
[34] R. Sonnier,et al. Incorporation of modified Stöber silica nanoparticles in polystyrene/polyamide-6 blends: Coalescence inhibition and modification of the thermal degradation via controlled dispersion at the interface , 2014 .
[35] I. Huynen,et al. Polymer/carbon based composites as electromagnetic interference (EMI) shielding materials , 2013 .
[36] Yutian Zhu,et al. Design of electrical conductive composites: tuning the morphology to improve the electrical properties of graphene filled immiscible polymer blends. , 2012, ACS applied materials & interfaces.
[37] H. Deng,et al. Preparation of high performance conductive polymer fibres from double percolated structure , 2011 .
[38] Xiangmin Han,et al. A Review of CO2 Applications in the Processing of Polymers , 2003 .
[39] D. R. Lloyd,et al. The effects of viscosity on coalescence-induced coalescence , 2003 .
[40] D. R. Paul,et al. Formation of Co-continuous Structures in Melt-Mixed Immiscible Polymer Blends , 2003 .
[41] C. J. Carriere,et al. Interfacial tension of poly(lactic acid)/polystyrene blends , 2002 .
[42] C. J. Carriere,et al. Interfacial tension of polycaprolactone/polystyrene blends by the imbedded fiber retraction method† , 2002 .
[43] J. Dam,et al. On the coarsening of co-continuous morphologies in polymer blends: effect of interfacial tension, viscosity and physical cross-links , 2000 .
[44] C. J. Carriere,et al. Molecular Weight Dependence of Polystyrene/Poly(methyl methacrylate) Interfacial Tension Probed by Imbedded-Fiber Retraction , 1994 .
[45] Leon P.B.M. Janssen,et al. Supercritical carbon dioxide as a green solvent for processing polymer melts: Processing aspects and applications , 2006 .
[46] C. Tzoganakis,et al. Measurement of interfacial tension in PS/LDPE melts saturated with supercritical CO2 , 2004 .