Contact resistance in sub-micron and nanoscale organic thin-film transistors

Abstract

Two improved methods for evaluating contact resistance in organic thin-film transistors (TFTs) are presented. These methods can be applied to TFTs with any arbitrary geometry and are also suitable for retroactive analysis of current-voltage characteristics. The first method is based on the analysis of the differential conductance of TFTs and in separating the conductivity contributions from the contacts and the channel. This method provides accurate results when the contact resistance is approximately 0.1–10 times the channel resistance. The second method is especially applicable to nanoscale and short channel length TFTs. The minimum value of differential on-resistance as a function of drain bias is used to separate the contributions of the channel and contact resistances at various drain voltages. This method is accurate when the contact resistance is approximately 0.3–10 times the channel resistance, as verified by simulations. It works even when there is no distinct saturation in current-voltage characteristics with increasing drain voltage. Both methods have been applied to experimental data from organic TFTs with channel lengths in the range 10 nm to 5 μm. • Two novel methods of extracting contact resistance in OTFTs are introduced. • Contact resistance of various channel lengths OTFTs are extracted and analyzed. • Effects of contact resistance in short channel pentacene TFTs are discussed. • New design of ultra-short channel TFTs is proposed to improve carrier injection.