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Article Abstract
In this paper, we demonstrate high-performance and hysteresis-free solution-processed indium-gallium-zinc oxide (IGZO) thin-film transistors (TFTs) and high-frequency-operating seven-stage ring oscillators using a low-temperature photochemically activated AlO/ZrO bilayer gate dielectric. It was found that the IGZO TFTs with single-layer gate dielectrics such as AlO, ZrO, or sodium-doped AlO exhibited large hysteresis, low field-effect mobility, or unstable device operation owing to the interfacial/bulk trap states, insufficient band offset, or a substantial number of mobile ions present in the gate dielectric layer, respectively. To resolve these issues and to explain the underlying physical mechanisms, a series of electrical analyses for various single- and bilayer gate dielectrics was carried out. It is shown that compared to single-layer gate dielectrics, the AlO/ZrO gate dielectric exhibited a high dielectric constant of 8.53, low leakage current density (∼10 A cm at 1 MV cm), and stable operation at high frequencies. Using the photochemically activated AlO/ZrO gate dielectric, the seven-stage ring oscillators operating at an oscillation frequency of ∼334 kHz with a propagation delay of <216 ns per stage were successfully demonstrated on a polymeric substrate.
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