Spinning Solid and Hollow Polymer-Free Carbon Nanotube Fibers

Polymer‐free carbon nanotube fibers are spun from aqueous dispersions using a flocculation‐based process that was developed. It produces hollow fibers, folded ribbon fibers, and solid fibers (see Figure). The fibers spun from single‐walled nanotubes exhibit relatively high electrical conductivities...

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Published in:Advanced materials (Weinheim) Vol. 17; no. 5; pp. 614 - 617
Main Authors: Kozlov, M. E., Capps, R. C., Sampson, W. M., Ebron, V. H., Ferraris, J. P., Baughman, R. H.
Format: Journal Article
Language:English
Published: Weinheim WILEY-VCH Verlag 08-03-2005
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Abstract Polymer‐free carbon nanotube fibers are spun from aqueous dispersions using a flocculation‐based process that was developed. It produces hollow fibers, folded ribbon fibers, and solid fibers (see Figure). The fibers spun from single‐walled nanotubes exhibit relatively high electrical conductivities (∼140 S cm–1 at room temperature) and electrochemical capacitances (∼100 F g–1) after annealing. Fiber supercapacitors are made from the spun fibers.
AbstractList Polymer‐free carbon nanotube fibers are spun from aqueous dispersions using a flocculation‐based process that was developed. It produces hollow fibers, folded ribbon fibers, and solid fibers (see Figure). The fibers spun from single‐walled nanotubes exhibit relatively high electrical conductivities (∼140 S cm–1 at room temperature) and electrochemical capacitances (∼100 F g–1) after annealing. Fiber supercapacitors are made from the spun fibers.
Polymer-free carbon nanotube fibers are spun from aqueous dispersions using a flocculation-based process that was developed. It produces hollow fibers, folded ribbon fibers, and solid fibers. The fibers spun from single-walled nanotubes exhibit relatively high electrical conductivities (~140 S cm-1 at room temperature) and electrochemical capacitances (~100 Fg-1 ) after annealing. Fiber supercapacitors are made from the spun fibers.
Author Kozlov, M. E.
Sampson, W. M.
Ebron, V. H.
Capps, R. C.
Ferraris, J. P.
Baughman, R. H.
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  surname: Kozlov
  fullname: Kozlov, M. E.
  email: Mikhail.Kozlov@utdallas.edu
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  givenname: R. C.
  surname: Capps
  fullname: Capps, R. C.
  organization: The NanoTech Institute, University of Texas at Dallas, Richardson, TX 75080, USA
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  givenname: W. M.
  surname: Sampson
  fullname: Sampson, W. M.
  organization: The NanoTech Institute, University of Texas at Dallas, Richardson, TX 75080, USA
– sequence: 4
  givenname: V. H.
  surname: Ebron
  fullname: Ebron, V. H.
  organization: The NanoTech Institute, University of Texas at Dallas, Richardson, TX 75080, USA
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  givenname: J. P.
  surname: Ferraris
  fullname: Ferraris, J. P.
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  givenname: R. H.
  surname: Baughman
  fullname: Baughman, R. H.
  email: Ray.Baughman@utdallas.edu
  organization: E-mail: Ray.Baughman@utdallas.edu
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Notes This work was supported by DARPA grant MDA 972-02-C-005, DOD/USARO grant W911NF-04-1-0174, the Texas Advanced Technology Program grant 009741-0130-2003, and the Robert A. Welch Foundation.
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This work was supported by DARPA grant MDA 972‐02‐C‐005, DOD/USARO grant W911NF‐04‐1‐0174, the Texas Advanced Technology Program grant 009741‐0130‐2003, and the Robert A. Welch Foundation.
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Snippet Polymer‐free carbon nanotube fibers are spun from aqueous dispersions using a flocculation‐based process that was developed. It produces hollow fibers, folded...
Polymer-free carbon nanotube fibers are spun from aqueous dispersions using a flocculation-based process that was developed. It produces hollow fibers, folded...
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SubjectTerms Carbon nanotubes
Carbon nanotubes, single‐walled
Fibers
single-walled
Supercapacitors
Title Spinning Solid and Hollow Polymer-Free Carbon Nanotube Fibers
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