Weidling, Adam2024-01-052024-01-052021https://hdl.handle.net/11299/259669University of Minnesota Ph.D. dissertation. ---2021. Major: Electrical/Computer Engineering. Advisor: Bethanie Stadler. 1 computer file (PDF); v, 176 pages.Metal oxide semiconductors such as InGaZnO and its derivatives are a promising group of materials with high mobility, low cost, and optical transparency. As the development of flexible electronics continues, these materials have several advantages for thin-film transistors over amorphous silicon such as high field effect mobility, and the ease of synthesis and deposition. The ability to create high-quality semiconductor materials compatible with low-temperature processing has been an emerging area of research over the past few decades. This research has included alternative synthesis routes, processing methods, and substrate materials. The ability to develop high-quality flexible devices has vast societal impact in leisure with applications such as next generation flexible displays, as well as in conformal medical devices for health monitoring. In this work, photonic curing is introduced as a method to rapidly and efficiently create high-quality thin-film transistors. This work addresses the importance of material parameters on the transient curing response and design guidelines for developing high-quality devices. Photonic cured metal oxide TFTs were compared with a thermally annealed baseline to study the TFT performance and chemical composition. Despite the short time scale in which the photonic curing process operates over, the photonic cured devices had a higher field effect mobility than the thermally annealed devices having mobilities of 21.8 cm^2V^-1s^-1 and 17.1 cm^2V^-1s^-1 respectively. A 3D model was developed to simulated the photonic curing process and to explore the impact of different materials and device layouts on the thermal profiles. The development of a robust fabrication platform for flexible electronics has been a challenge in the development of higher-complexity flexible circuits. To overcome this, a robust photonic lift-off process using a light absorber layer was developed using a low-CTE polymer. The large area and uniformity of the lamp energy allows for rapid and large area polymer delamination. In addition to providing a robust platform for fabrication, this process allows for fully-photonic processed fabrication including both semiconductor processing and substrate lift-off. The ability to use photonic curing for both semiconductor processing and polymer delamination allows for process times to be greatly reduced, and provides a new pathway towards fabricating next-generation high-performance flexible electronics.enflexible electronicsphotonic curingphotonic lift-offsol-gelthin-film transistorThesis or Dissertation