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Yan H, Chen Z, Zheng Y, Newman C, Quinn JR, Dotz F, Kastler M, Facchetti A (2009) A high-mobility electron-transporting polymer for printed transistors. Phys Today 58(5):53–58īraun S, Salaneck WR, Fahlman M (2009) Energy-level alignment at organic/metal and organic/organic interfaces. Malliaras G, Friend R (2005) An organic electronics primer. McCullough RD (1998) The chemistry of conducting polythiophenes. Ong BS, Wu Y, Liu P, Gardner S (2004) High-performance semiconducting polythiophenes for organic thin-film transistors. Adv Mater 15(11):917–922īao Z, Dodabalapur A, Lovinger AJ (1996) Soluble and processable regioregular poly(3-hexylthiophene) for thin film field-effect transistor applications with high mobility. Halik M, Klauk H, Zschieschang U, Schmid G, Ponomarenko S, Kirchmeyer S, Weber W (2003) Relationship between molecular structure and electrical performance of oligothiophene organic thin film transistors. Hunt A (2007) Complete A-Z chemistry handbook, 3rd edn. In: Chen J, Cranton W, Fihn M (eds) Handbook of visual display technology. Liu F, Ferdous S, Briseno AL (2012) Polymer thin film transistors. Redinger D, Payne M (2012) Organic TFTs: solution-processable small-molecule semiconductors. Klauk H (2012) Organic thin film transistors based on vacuum-deposited small-molecule semiconductors. Zschieschang U, Ante F, Yamamoto T, Takimiya K, Kuwabara H, Ikeda M, Sekitani T, Someya T, Kern K, Klauk H (2010) Flexible low-voltage organic transistors and circuits based on a high-mobility organic semiconductor with good air stability. Jeon J, Murmann B, Bao Z (2010) Full-swing and high-gain pentacene logic circuits on plastic substrate. Klauk H, Zschieschang U, Pflaum J, Halik M (2007) Ultralow-power organic complementary circuits. OTFT-driven flexible color AMOLED display using dual protection scheme for organic semiconductor patterning. Nakajima Y, Takei T, Tsuzuki T, Suzuki M, Fukagawa H, Yamamoto T, Tokito S (2009) Fabrication of 5.8-in. Mizukami M, Hirohata N, Iseki T, Ohtawara K, Tada T, Yagyu S, Abe T, Suzuki T, Fujisaki Y, Inoue Y, Tokito S, Kurita T (2006) Flexible AM OLED panel driven by bottom-contact OTFTs. eBook & tablet market evolution conference, SID Display Week. McGoldrick K (2011) Flexible displays ready for lift off. Yoneya N, Ono H, Ishii Y, Himori K, Hirai N, Abe H, Yumoto A, Kobayashi N, Nomoto K, Urabe T (2011) Flexible electrophoretic display driven by solution-processed OTFTs. Appl Phys Lett 80(6):1088–1090īurns S (2010) QUE: an e-reader built using flexible display technology. Sheraw CD, Zhou L, Huang JR, Gundlach DJ, Jackson TN, Kane MG, Hill IG, Hammond MS, Campi J, Greening BK, Francl J, West J (2002) Organic thin-film transistor-driven polymer-dispersed liquid crystal displays on flexible polymeric substrates.

Nomoto K, Noda M, Kobayashi N, Katsuhara M, Yumoto A, Ushikura S-i, Yasuda R-i, Hirai N, Yukawa G and Yagi I (2011) Rollable OLED display driven by organic TFTs. Sekitani T, Iba S, Kato Y, Noguchi Y, Someya T, Sakurai T (2005) Ultraflexible organic field-effect transistors embedded at a neutral strain position. Mas-Torrent M, Rovira C (2011) Role of molecular order and solid-state structure in organic field-effect transistors. In: Klauk H (ed) Organic electronics: materials, manufacturing and applications. Kelley T (2006) High-performance pentacene transistors. This process is experimental and the keywords may be updated as the learning algorithm improves. These keywords were added by machine and not by the authors. These are linked to device behaviour, with a focus on the key material and design issues, which currently limit TFT performance, such as metal/organic contacts, and ambient and bias stability effects. Other topics include molecular ordering, carrier transport, TFT architecture, and the deposition of both semiconductor and dielectric materials, together with their properties. This chapter reviews work in this field, and starts by introducing some of the key organic chemistry concepts, which underpin the semiconducting behaviour of these materials. A large number of organic TFT materials now display carrier mobility values approaching, or exceeding, those of a-Si:H, and this has stimulated considerable interest in using them for low cost, flexible substrate applications, such as RFID tags, and e-reader displays.