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High Dielectric Performances of Flexible and Transparent Cellulose Hybrid Films Controlled by Multidimensional Metal Nanostructures
Authors:Sangyoon Ji  Jiuk Jang  Eunjin Cho  Si‐Hoon Kim  Eun‐Seok Kang  Jihoon Kim  Han‐Ki Kim  Hoyoul Kong  Sun‐Kyung Kim  Ju‐Young Kim  Jang‐Ung Park
Affiliation:1. School of Materials Science and Engineering, Wearable Electronics Research Group, Ulsan National Institute of Science and Technology (UNIST), Ulsan Metropolitan City, Republic of Korea;2. New Material Team, Materials & Devices Advanced Research Institute, LG Electronics Inc., Seocho‐gu, Seoul, Republic of Korea;3. Division of Advanced Materials Engineering, Kongju National University, Cheonan, Chungchungnam‐do, Republic of Korea;4. Department of Advanced Materials Engineering for Information and Electronics, Kyung‐Hee University, Yongin‐si, Gyeonggi‐do, Republic of Korea;5. Korea Research Institute of Chemical Technology (KRICT), Division of Chemical R&BD at Ulsan, Ulsan, Republic of Korea;6. Department of Applied Physics, Kyung Hee University, Gyeonggi‐do, Republic of Korea
Abstract:Various wearable electronic devices have been developed for extensive outdoor activities. The key metrics for these wearable devices are high touch sensitivity and good mechanical and thermal stability of the flexible touchscreen panels (TSPs). Their dielectric constants (k) are important for high touch sensitivities. Thus, studies on flexible and transparent cover layers that have high k with outstanding mechanical and thermal reliabilities are essential. Herein, an unconventional approach for forming flexible and transparent cellulose nanofiber (CNF) films is reported. These films are used to embed ultralong metal nanofibers that serve as nanofillers to increase k significantly (above 9.2 with high transmittance of 90%). Also, by controlling the dimensions and aspect ratios of these fillers, the effects of their nanostructures and contents on the optical and dielectric properties of the films have been studied. The length of the nanofibers can be controlled using a stretching method to break the highly aligned, ultralong nanofibers. These nanofiber‐embedded, high‐k films are mechanically and thermally stable, and they have better Young's modulus and tensile strength with lower thermal expansion than commercial transparent plastics. The demonstration of highly sensitive TSPs using high‐k CNF film for smartphones suggests that this film has significant potential for next‐generation, portable electronic devices.
Keywords:cellulose  high dielectric constants  metal nanofibers  transparent films  touchscreen panels
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