A numerical procedure to calculate the drain-current (ID) vs. gate-voltage (VG) characteristics from numerical solutions of the Poisson equation for organic Thin-Film Transistors (TFTs) is presented. Polaron transport is modeled as two-dimensional charge transport in a semiconductor having free-carrier density of states proportional to the density of molecules and traps with energy equal to the polaron-hopping barrier. The simulated ID-VG curves are proportional to the product of the density of free carriers, calculated as a function of VG, and the intrinsic mobility, assumed to be a constant independent of temperature. The presence of traps in the oxide was also taken into account in the model, which was applied to a TFT made with six monolayers of pentacene grown on an oxide substrate. The polaron-hopping barrier determines the temperature dependence of the simulated ID-VG curves, trapping in the oxide is responsible for current reduction at high bias and the slope of the characteristics near threshold is related to the metal-semiconductor work-function difference. The values of the model parameters yielding the best match between calculations and experiments are consistent with previous experimental results and theoretical predictions. Therefore, this model enables to extract both physical and technological properties of thin-film devices from the temperature-dependent dc characteristics.
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28 June 2014
Research Article|
June 24 2014
Trap densities and transport properties of pentacene metal–oxide–semiconductor transistors: II—Numerical modeling of dc characteristics
A. F. Basile;
A. F. Basile
a)
1Department of Physics and Astronomy,
University of Bologna
, Bologna 40127, Italy
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A. Kyndiah;
A. Kyndiah
2
Institute for the Study of Nano-structured Materials
, CNR, Bologna 40129, Italy
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F. Biscarini;
F. Biscarini
2
Institute for the Study of Nano-structured Materials
, CNR, Bologna 40129, Italy
3Department of Life Sciences,
University of Modena and Reggio Emilia
, Modena 41125, Italy
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B. Fraboni
B. Fraboni
1Department of Physics and Astronomy,
University of Bologna
, Bologna 40127, Italy
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J. Appl. Phys. 115, 244505 (2014)
Article history
Received:
April 14 2014
Accepted:
June 11 2014
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Citation
A. F. Basile, A. Kyndiah, F. Biscarini, B. Fraboni; Trap densities and transport properties of pentacene metal–oxide–semiconductor transistors: II—Numerical modeling of dc characteristics. J. Appl. Phys. 28 June 2014; 115 (24): 244505. https://doi.org/10.1063/1.4884856
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