Conduction Mechanism Based Model of Organic Field Effect Transistor Structure

Rajko M. Šašić; P.M. Lukić

doi:10.4028/www.scientific.net/MSF.555.125

Paper Titles

Modeling and Investigation of SiGe Based MOSFET Structure Transport Characteristics
p.101

Simulation Study of Granular Compaction Dynamics under Vertical Tapping
p.107

Plasma Etching for the Application to Low-K Dielectrics Devices
p.113

Relevance of Polaron/Soliton-Like Transport Mechanisms in Cascade Resonant Isomeric Transitions of Q1D-Molecular Chains
p.119

Conduction Mechanism Based Model of Organic Field Effect Transistor Structure
p.125

Theoretical Assessment of Calcium Arsenates Stability: Application in the Treatment of Arsenic Contaminated Waste
p.131

Characterization of Target Material for X-Ray Generator by Monte Carlo Method
p.137

Monte Carlo Calculation of X-Rays Deposited Energy in CdZnTe Detector
p.141

A Model of Gamma-Ray Irradiation Effects in Silicon Dioxide Films and on Silicon Dioxide - Silicon Interface
p.147

HomeMaterials Science ForumMaterials Science Forum Vol. 555Conduction Mechanism Based Model of Organic Field...

Conduction Mechanism Based Model of Organic Field Effect Transistor Structure

Abstract:

Carriers mobility model of olygomer and polymer semiconductor based OFET (Organic Field Effect Transistor) structures is presented in this paper. Starting from the conduction mechanism in the mentioned organic materials, a carrier mobility dependence on temperature, electric field and trap density μ(T,E,NT) was investigated, inspiring directly the current-voltage I(V) model of OFET structures. Subsequent simulations were also performed and the obtained results compared with the data available in the literature.

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Materials Science Forum (Volume 555)

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125-130

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.555.125

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Online since:

September 2007

Authors:

Rajko M. Šašić, P.M. Lukić

Keywords:

Carrier Mobility Model, Electrical Characteristics, Organic TFT Model, Simulation

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