6 February 2012 A thin porous substrate using bonded particles for reverse-emulsion electrophoretic displays
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Proceedings Volume 8280, Advances in Display Technologies II; 82800R (2012) https://doi.org/10.1117/12.909252
Event: SPIE OPTO, 2012, San Francisco, California, United States
Abstract
A thin porous layer of bonded ceramic microparticles has been developed to provide structural integrity and a stationary matrix for use in reflective-mode reverse-emulsion electrophoretic displays (REED), based on self-assembled nanodroplets dispersed in a non-polar liquid. REED ink uses low-cost materials and manufacturing processes, yet is capable of video speed and low voltage operation below 10 V. Porous layers of titanium dioxide (TiO2) are prepared as thin as 10 microns by fluidizing the particles in a water-based slurry with polymeric adhesive. The slurry is distributed between glass shear plates, one of which serves as the substrate for the working device. Particle morphology is examined using scanning electron microscopy and layer uniformity is characterized by opacity measurements using a throughbeam fiber optic sensor. Performance of the bonded matrix with REED ink is compared to baseline performance of a paste mixture, comprised of the same ink and unbonded TiO2 particles. Results show that at 25% volume fraction, the bonded substrate improves image bistability and is better able to maintain both light and dark intensity after extensive switching. The same bonded substrate also improves image bistability when power is disconnected, even compared to a paste with 40% volume fraction of TiO2.
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M. Ahumada, M. Bryning, R. Cromer, M. Hartono, S. J. Lee, "A thin porous substrate using bonded particles for reverse-emulsion electrophoretic displays", Proc. SPIE 8280, Advances in Display Technologies II, 82800R (6 February 2012); doi: 10.1117/12.909252; https://doi.org/10.1117/12.909252
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