The high-frequency characteristics of AlGaN/GaN high-electron-mobility transistors (HEMTs) and metal-insulator-semiconductor HEMTs (MIS-HEMTs) are investigated under ultraviolet (UV) radiation with 365 nm wavelength. When HEMTs and MIS-HEMTs are illuminated with an UV source, their drain currents increase apparently owing to the generated photocurrent. Nevertheless, they show different high-frequency response to the UV light. For HEMTs, the peak cutoff frequency (fT) and maximum oscillation frequency (fmax) of illuminated devices are 20% and 10% higher than those in dark condition, respectively, owing to the increased transconductance. For MIS-HEMTs, however, their high-frequency performances are degraded when transistors are subject to light exposure. The degradations of peak fT and fmax are around 3.7% and 18%, respectively. The small-signal model parameters relevant to the high-frequency characteristics were extracted to explain these phenomena. Additional trapped charges in the SiN gate dielectric induced by UV light would be responsible for the degraded high-frequency parameters in illuminated MIS-HEMTs. These experimental results are important for designing a suitable GaN-based HEMT for optoelectronic applications.
In this paper, we present the dc and high-frequency characteristics of trigate polycrystalline-silicon (poly-Si) thin-film transistors (TFTs) for RF applications. Trigate TFTs were fabricated using a 3D-IC process and designed with a multi-finger gate and multi-channel configuration. To obtain an optimal device design guideline, different source/drain (S/D) extension dimensions and channel layouts are investigated. We find that devices with a shorter or wider extension have higher cutoff frequencies (fT) and maximum oscillation frequencies (fmax) owing to their lower S/D resistances. In addition, the high-frequency performance can be further improved by adopting the tapered channel structure, where the channel width increases gradually from the source to the drain. For the optimal device designs, the values of fT and fmax are around 25 GHz and 30 GHz, respectively. The high fT and fmax as well as excellent gate controllability in our devices indicate the trigate poly-Si TFT could be a suitable candidate for low-cost RFIC applications.
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