Computational thermal model for nanotube based electronic display

Electro-thermal transport in a new class of nanotube bundle transistors and their application to electronic displays is considered. The transistors are made of nanocomposites composed of isotropic 2D ensembles of nanotubes or nanowires in a plastic or glass substrate. The random nanotube network is...

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Bibliographic Details
Main Authors: Kumar, S., Alam, M.A., Murthy, J.Y.
Format: Conference Proceeding
Language:English
Subjects:
Computational modeling
Computer displays
Conductivity
Contact resistance
Distributed computing
Nanocomposites
Nanowires
Power distribution
Resistance heating
Temperature distribution
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Summary:Electro-thermal transport in a new class of nanotube bundle transistors and their application to electronic displays is considered. The transistors are made of nanocomposites composed of isotropic 2D ensembles of nanotubes or nanowires in a plastic or glass substrate. The random nanotube network is generated numerically and simulated using a finite volume scheme. The voltage and spatial power distribution in the transistor is computed in the linearly-biased regime. The computed power distribution is used as Joule heat source in a Fourier heat transport model for the nanotube network and substrate and the temperature rise in tube network and substrate are predicted. The effect of tube-tube contact conductance, tube-substrate contact conductance and substrate-tube conductivity ratio on the temperature rise is analyzed. The effect of convective cooling on the temperature rise is investigated for a range of heat transfer coefficients between the display surface and the ambient air. The tube-substrate contact resistance emerges as a dominant resistive component for the tube temperature rise, but is found to be insignificant for the substrate temperature rise. Tube conductivity and tube-tube contact conductance are found to have only a minor effect on lateral heat spreading because the dominant resistance to heat removal lies on the substrate and the air side for the range of parameters investigated
ISSN:1087-9870
2577-0799
DOI:10.1109/ITHERM.2006.1645493