Design and fabrication of organic complementary circuits
- 1 May 2001
- journal article
- research article
- Published by AIP Publishing in Journal of Applied Physics
- Vol. 89 (9) , 5125-5132
- https://doi.org/10.1063/1.1362635
Abstract
We have used a simple model description of single field effect transistor characteristics to design organic complementary circuits ranging in complexity from simple inverters through 48-stage shift registers and three-bit row decoders. The circuits were fabricated using standard silicon photolithographic techniques to define the metal, insulator, and interconnect levels. The ohmic source and drain contacts and part of the interconnect metallization were formed by electroless/immersion deposition of Ni-P/Au on prepatterned TiN. The n-type and p-type organic semicondcutors were evaporated onto these substrates to complete the circuits. Measured circuit characteristics were in reasonable agreement with simulations based on the simple device model.This publication has 29 references indexed in Scilit:
- Anodization and Microcontact Printing on Electroless Silver: Solution-Based Fabrication Procedures for Low-Voltage Electronic Systems with Organic Active ComponentsLangmuir, 2000
- Condensation Model for Cylindrical Nanopores Applied to Realistic Porous Glass Generated by Molecular SimulationLangmuir, 2000
- A soluble and air-stable organic semiconductor with high electron mobilityNature, 2000
- Soluble Regioregular Polythiophene Derivatives as Semiconducting Materials for Field-Effect TransistorsChemistry of Materials, 1999
- Low-voltage 0.1 μm organic transistors and complementary inverter circuits fabricated with a low-cost form of near-field photolithographyApplied Physics Letters, 1999
- Organic field-effect transistors and all-polymer integrated circuitsOptical Materials, 1999
- Organic complementary ring oscillatorsApplied Physics Letters, 1999
- Low-Voltage Organic Transistors on Plastic Comprising High-Dielectric Constant Gate InsulatorsScience, 1999
- Synthesis, Material Properties, and Transistor Performance of Highly Pure Thiophene OligomersChemistry of Materials, 1995
- Gas-Sensitive Schottky Gated Field Effect Transistors Utilizing Poly(3-alkylthiophene) FilmsJapanese Journal of Applied Physics, 1991