Vapor Phase Polymerized Conductive Poly(3,4-ethylenedioxythiophene) Thin Films

Description:

Vapor Phase Polymerized Conductive PEDOT Thin Films

 

Conductive films can utilize materials across a wide swath of conventional technologies, with particular use of indium tin oxide (ITO). In addition to favorable conductivity, this material affords the resulting conductive films with other characteristics (e.g., transparency) that make the films amenable to the wide range of applications. ITO is, however, a product of indium, which is a raw material in relatively short supply and, accordingly, continues to in-crease in price with demand growth for thin, conductive films. Moreover, alt-hough favored for certain characteristics, films that utilize ITO can suffer from cracking and brittle failures when subject to bending. This feature some-what limits use of these ITO-based films in combination, e.g., with flexible substrates.

The present technology addresses concerns with ITO-based films to provide candidate materials for use in connection with flexible electronics, and en-compasses films and material layers comprising poly(3,4 ethylenedioxytho-pene) (PEDOT). The PEDOT film is made utilizing vapor phase polymerization (VPP) with defined parameters and components. The crystalline structure is favorably organized for films to achieve conductivity in excess of 1000 S/cm, and thus suitable for use as a replacement for ITO-based films.

 

 

APPLICATIONS

 

 Consumer Electronics (e.g. phones, televisions, tablet computers, etc.)

 

 Enhancement of solar cells and light-emitting diode (LED) devices

 

 Anti-static coatings

 

ADVANTAGES

 

 High Conductivity: in excess of 1000 S/cm, well-above most conventional technologies. Conductivity can be tailored based on the application

 

 Transmittance: exhibits excellent transmission in excess of 85%

 

 Reliability: outperforms both PEDOT:PSS and ITO in fatigue test of flexure dimension

 

 Transparency: optically transparent and/or exhibits optical properties that transmit light through > 90%

 

 Stretchability: very strechable, conductivity increases upon stretching

 

U.S. Patent Application

14/212,559

 

INVENTORS

 

♦ Dr. Wayne Jones is a Professor and Chairman of Inorganic and Materials Chemistry at the State University of New York (SUNY) at Binghamton. His research interests involve the study of photo-induced electron and energy transfer processes in inorganic and polymer systems.

 

♦ Dr. William Bernier is a Research Professor of Chemistry and Materials Science and Engineering at the State University of New York (SUNY) at Binghamton. His research interests include materials and process development for semiconductor for Pb-free semiconductor interconnection, electronic circuit packaging, nanotechnology, and energy storage technology.

Patent Information:
For Information, Contact:
Scott Hancock
Director, IP Management and Licensing
Binghamton University
(607) 777-5874
shancock@binghamton.edu
Inventors:
Wayne Jones
William Bernier
Nicholas Ravvin
Kenneth Skorenko
Keywords:
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