U
Ute Zschieschang
Researcher at Max Planck Society
Publications - 171
Citations - 12033
Ute Zschieschang is an academic researcher from Max Planck Society. The author has contributed to research in topics: Thin-film transistor & Transistor. The author has an hindex of 46, co-authored 162 publications receiving 11055 citations.
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Ultralow-power organic complementary circuits
TL;DR: This work demonstrates an organic circuit with very low power consumption that uses a self-assembled monolayer gate dielectric and two different air-stable molecular semiconductors (pentacene and hexadecafluorocopperphthalocyanine, F16CuPc) to implement transistors, circuits, displays and sensors on arbitrary substrates.
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High-mobility polymer gate dielectric pentacene thin film transistors
TL;DR: In this article, a spin-coated polymer gate dielectric layer was used to obtain a polyvinylphenol-based copolymer-based transistor with a carrier mobility as large as 3 cm2/V's and sub-threshold swing as low as 0.5 V/decade.
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Flexible organic transistors and circuits with extreme bending stability
TL;DR: This work demonstrates organic transistors and complementary circuits that continue to operate without degradation while being folded into a radius of 100 μm, enabled by a very thin plastic substrate, an atomically smooth planarization coating and a hybrid encapsulation stack that places the transistors in the neutral strain position.
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Organic Nonvolatile Memory Transistors for Flexible Sensor Arrays
Tsuyoshi Sekitani,Tomoyuki Yokota,Ute Zschieschang,Hagen Klauk,Siegfried Bauer,Ken Takeuchi,Makoto Takamiya,Takayasu Sakurai,Takao Someya +8 more
TL;DR: A sensor matrix is realized that detects the spatial distribution of applied mechanical pressure and stores the analog sensor input as a two-dimensional image over long periods of time by integrating a flexible array of organic floating-gate transistors with a pressure-sensitive rubber sheet.
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Organic transistors manufactured using inkjet technology with subfemtoliter accuracy
TL;DR: Subfemtoliter inkjet printing is demonstrated by demonstrating metal contacts with single-micrometer resolution on the surface of high-mobility organic semiconductors to create high-performance p-channel and n-channel transistors and low-power complementary circuits.