Bolometric properties of semiconducting and metallic single-walled carbon nanotube composite films

Single-walled carbon nanotubes (SWNTs) have shown interesting bolometric properties, making them good candidates for the detection of infrared and terahertz radiation. However, little has been reported on the bolometric characteristics of SWNT as a function of their chirality or the possible influence of composite morphology on these properties. The separation of SWNTs based on chirality allows for almost purely semiconductive or metallic SWNTs to be studied. The current study focuses on the bolometric performance of self-assembled composite films of SWNTs. The dependence of these properties on the chirality of the SWNTs was evaluated. To this end, metallic, semiconducting, and a 1:1 mixture of metallic and semiconductive were studied. Also, a theoretical model based on the Wiedemann-Franz law is used to explain the resistance of the SWNT composite films as a function of temperature. Results show that the composite morphology has a significant impact on bolometer performance, with cracked composite films containing highly aligned SWNT arrays suspended over a silicon substrate showing superior responsivity values due to higher thermal isolation. Uncracked composite films showed superior thermal coefficient of resistance values (α = -6.5%25/K), however, the responsivity was lower due to lower thermal isolation. © 2015 American Chemical Society.

bolometer; carbon nanotube; chirality; composite; infrared detector Bolometers; Carbon; Carbon films; Carbon nanotubes; Chirality; Composite materials; Infrared detectors; Morphology; Nanocomposite films; Semiconducting films; Single-walled carbon nanotubes (SWCN); Terahertz waves; Yarn; Bolometric properties; Composite morphology; Metallic single-walled carbon nanotubes; Single-walled carbon nanotube (SWNTs); Terahertz radiation; Theoretical modeling; Thermal coefficient of resistance; Wiedemann-Franz law; Composite films

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