Electronic Durability of Flexible Transparent Films from Type-Specific Single-Wall Carbon Nanotubes Metadata

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Title

  • Main Title Electronic Durability of Flexible Transparent Films from Type-Specific Single-Wall Carbon Nanotubes

Creator

  • Author: Harris, J
    Creator Type: Personal
  • Author: Iyer, S
    Creator Type: Personal
  • Author: Bernhardt, A
    Creator Type: Personal
  • Author: Huh, JY
    Creator Type: Personal
  • Author: Hudson, S
    Creator Type: Personal
  • Author: Fagan, J
    Creator Type: Personal
  • Author: Hobbie, E.
    Creator Type: Personal

Contributor

  • Sponsor: United States. Department of Energy.
    Contributor Type: Organization
  • Sponsor: United States. Department of Energy. Office of Energy Efficiency and Renewable Energy.
    Contributor Type: Organization
    Contributor Info: USDOE Office of Energy Efficiency and Renewable Energy (EERE)

Publisher

  • Name: North Dakota State Univeristy
    Place of Publication: United States

Date

  • Creation: 2011-12-11

Language

  • English

Description

  • Content Description: The coupling between mechanical flexibility and electronic performance is evaluated for thin films of metallic and semiconducting single-wall carbon nanotubes (SWCNTs) deposited on compliant supports. Percolated networks of type-purified SWCNTs are assembled as thin conducting coatings on elastic polymer substrates, and the sheet resistance is measured as a function of compression and cyclic strain through impedance spectroscopy. The wrinkling topography, microstructure and transparency of the films are independently characterized using optical microscopy, electron microscopy, and optical absorption spectroscopy. Thin films made from metallic SWCNTs show better durability as flexible transparent conductive coatings, which we attribute to a combination of superior mechanical performance and higher interfacial conductivity.
  • Physical Description: 881-887

Subject

  • STI Subject Categories: 77 Nanoscience And Nanotechnology
  • Keyword: Optical Microscopy
  • Keyword: Electron Microscopy
  • Keyword: Absorption Spectroscopy
  • Keyword: Polymers
  • Keyword: Substrates
  • Keyword: Strains
  • Keyword: Compression
  • Keyword: Thin Films
  • Keyword: Microstructure
  • Keyword: Flexibility
  • Keyword: Spectroscopy
  • Keyword: Carbon
  • Keyword: Impedance
  • Keyword: Coatings
  • Keyword: Topography
  • Keyword: Performance
  • Keyword: Nanotubes

Source

  • Journal Name: ACS Nano; Journal Volume: 6; Journal Issue: 1

Collection

  • Name: Office of Scientific & Technical Information Technical Reports
    Code: OSTI

Institution

  • Name: UNT Libraries Government Documents Department
    Code: UNTGD

Resource Type

  • Article

Format

  • Text

Identifier

  • Report No.: DOE/GO/88160-41
  • Grant Number: FG36-08GO88160
  • DOI: 10.1021/nn204383t
  • Office of Scientific & Technical Information Report Number: 1033927
  • Archival Resource Key: ark:/67531/metadc836378