Conductive Flexible Composites

About

Conventional transparent conductive materials, such as sputtered metal oxides (e.g. ITO, FTO) or polymers (PEDOT:PSS), require synthesis temperatures over 120 ˚C. Some flexible conductive composites can be fabricated at lower temperatures, however conductive media is typically deposited over the film, providing only in-plan conductivity. The University of Hawaii (UH) has developed a new composite integrating multi-functionalities such as corrosion resistance, lightweight and flexibility as well as tunable optoelectronics. Unlike most conductive flexible polymers, where media are coated on top providing only in-plane conductivity, our transparent-conductive-flexible composites (TCFC) innovate by allowing simultaneously optical transparency and out-of-plane electrical conductivity. This unique characteristic is permitted by highly conductive spheres protruding out of a transparent non-conductive polymer. TCFCs can be formed by pressing a particle/polymer mix between two substrates. Depending on the surface treatment pre-applied to the substrates, TCFCs can be either i) fully liberated to create free-standing films, ii) remain bonded to only one substrate or iii) permanently bonded to both substrates. UH has thus far been successful in fabricating proof-of-concept free-standing TCFCs using 50 micron silver particles embedded in a polymer. These free-standing films possess both high optical transmittance and high out-of-plane conductivity (R=0.27 Ω.cm2), significantly outperforming commercially available F:SnO2/glass (FTO) substrates. The fact that we are able to measure high out-of-plane conductivity demonstrates that the particles of the free-standing layer protrude from the polymer matrix.