Solution spinning of cellulose carbon nanotube composites using room temperature ionic liquids

Multiwall carbon nanotube (MWCNT)/cellulose composite fibers were processed from solutions in ethyl methylimidazolium acetate (EMIAc). Rheological percolation in MWCNT/Cellulose/EMIAc solution was observed above 0.01 mass fraction of MWCNT, while electrical percolation in oriented fibers was observe...

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Veröffentlicht in:	Polymer (Guilford) 2009-09, Vol.50 (19), p.4577-4583
Hauptverfasser:	Rahatekar, Sameer S., Rasheed, Asif, Jain, Rahul, Zammarano, Mauro, Koziol, Krzysztof K., Windle, Alan H., Gilman, Jeffrey W., Kumar, Satish
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Sprache:	eng
Schlagworte:	Applied sciences Carbon nanotubes Cellulose Composites Exact sciences and technology Fibers and threads Forms of application and semi-finished materials Ionic liquids Polymer industry, paints, wood Technology of polymers
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creator	Rahatekar, Sameer S. Rasheed, Asif Jain, Rahul Zammarano, Mauro Koziol, Krzysztof K. Windle, Alan H. Gilman, Jeffrey W. Kumar, Satish
description	Multiwall carbon nanotube (MWCNT)/cellulose composite fibers were processed from solutions in ethyl methylimidazolium acetate (EMIAc). Rheological percolation in MWCNT/Cellulose/EMIAc solution was observed above 0.01 mass fraction of MWCNT, while electrical percolation in oriented fibers was observed above 0.05 mass fraction of MWCNTs with respect to the weight of the cellulose. Cellulose orientation and crystal size were significantly higher in the composite than in the control cellulose fiber. In addition, in the composite fiber, carbon nanotube orientation was higher than cellulose orientation. At 0.05 mass fraction MWCNT, fiber tensile strength increased by about 25%, strain to failure increased by 100%, and modulus essentially remained unchanged. The composite fibers showed lower thermal shrinkage than the control cellulose fiber. The axial electrical conductivity at 0.1 mass fraction MWCNTs in these oriented fibers was more than 3000S/m. [Display omitted]
doi_str_mv	10.1016/j.polymer.2009.07.015
format	Article
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Rheological percolation in MWCNT/Cellulose/EMIAc solution was observed above 0.01 mass fraction of MWCNT, while electrical percolation in oriented fibers was observed above 0.05 mass fraction of MWCNTs with respect to the weight of the cellulose. Cellulose orientation and crystal size were significantly higher in the composite than in the control cellulose fiber. In addition, in the composite fiber, carbon nanotube orientation was higher than cellulose orientation. At 0.05 mass fraction MWCNT, fiber tensile strength increased by about 25%, strain to failure increased by 100%, and modulus essentially remained unchanged. The composite fibers showed lower thermal shrinkage than the control cellulose fiber. The axial electrical conductivity at 0.1 mass fraction MWCNTs in these oriented fibers was more than 3000S/m. 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Rheological percolation in MWCNT/Cellulose/EMIAc solution was observed above 0.01 mass fraction of MWCNT, while electrical percolation in oriented fibers was observed above 0.05 mass fraction of MWCNTs with respect to the weight of the cellulose. Cellulose orientation and crystal size were significantly higher in the composite than in the control cellulose fiber. In addition, in the composite fiber, carbon nanotube orientation was higher than cellulose orientation. At 0.05 mass fraction MWCNT, fiber tensile strength increased by about 25%, strain to failure increased by 100%, and modulus essentially remained unchanged. The composite fibers showed lower thermal shrinkage than the control cellulose fiber. The axial electrical conductivity at 0.1 mass fraction MWCNTs in these oriented fibers was more than 3000S/m. 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subjects	Applied sciences Carbon nanotubes Cellulose Composites Exact sciences and technology Fibers and threads Forms of application and semi-finished materials Ionic liquids Polymer industry, paints, wood Technology of polymers
title	Solution spinning of cellulose carbon nanotube composites using room temperature ionic liquids
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