Optimized Gate Metal Variant Structure for Graded-Channel (GC) Gate-Stack (GS) Double-Gate (DG) MOSFET to Enhance Switching Speed, Analog and RF Performance

Graded-channel gate-stack double-gate metal-oxide-semiconductor field-effect transistors (GC-GS-DG-MOSFETs) with symmetric single-material-gate-metal (D1), asymmetric single-material-gate-metal (D2 and D3), dual-material-gate-metal (D4 and D5), and triple-material-gate-metal (D6 and D7) have been investigated to optimize the best structure for ultra-fast digital logic circuit and RF microwave circuit applications. The work function (\({\varphi }_{m}=4.7\pm 0.2 eV)\) of the gate electrodes has been determined based on key performance indicators, such as offset current, the I_ON/I_OFF ratio, and threshold voltage. This study identifies the designs that offer improved switching speed and overall device performance by evaluating I_ON/I_OFF, subthreshold swing, and threshold voltage. It also illustrates the electric field distribution, surface potential, and energy band diagram of the channel for all proposed configurations. Analog/ RF performance has been estimated by investigating the transconductance (g_m), output conductance (g_d), early voltage (V_EA), output resistance R_o), transconductance generation factor (TGF), cut-off frequency (f_T), intrinsic device delay (s), transconductance frequency product (TFP), and gain-bandwidth product (GBP). Additionally, linearity parameters, such as higher-order transconductance (g_m2, g_m3), V_IP2, V_IP3, third-order intercept point (IIP₃), and third-order intermodulation distortion (IMD₃)) have also been assessed.