Physical Insights and Accurate Modeling of Transconductance in Body-Contacted Dynamically Depleted SOI MOSFETs

In this work, we present a physical understanding and a robust surface potential coupling relationship essential to accurately capture the transconductance in body-contacted (BC) dynamically depleted silicon-on-insulator (DDSOI) MOSFETs for varied body biases. It is observed that the crossover of transconductance for varied body biases occurs before the peak transconductance is reached for devices operating particularly in the saturation region. This phenomenon is investigated in detail and attributed to partial-depletion-to-full-depletion transition in the silicon body that occurs before the peak transconductance is reached, in the saturation region of operation. The proposed coupling relationship effectively captures this behavior, ensuring symmetry of the overall model around {V}_{\text {ds}} = 0 V and correct harmonic characteristics in linear and saturation regions, which are critical for RF IC design. An enhanced mobility model with improved body bias dependency has also been proposed that helps in the accurate validation of transconductance. The model is validated with state-of-the-art industry hardware data from GlobalFoundries. The model has been integrated into our new industry standard symmetric BSIM-SOI compact model framework.