DC and Analog/RF Performance Evaluation Using Dual Metal Gate Work Function Engineering of Junctionless Cylindrical Gate All Around Si Nanowire MOSFET Using NEGF Approach for Upcoming Sub 5 nm Technology Node

Present work investigates the DC and Analog/RF characteristics such as the drain current (I_D ), Transconductance (g_m) , Transconductance Generation Factor (TGF), Cut-off frequency (f_T) , Frequency Transconductance Product (FTP), Transit time (τ ), and the total resistance of the source region, drain region, and channel resistance (R_SD+CH) for Dual Metal (DM) Inversion Mode (IM) and Junctionless (JL) Cylindrical Gate All Around (CGAA) Silicon nanowire (SiNW) MOSFETs with 5 nm gate length using Silvaco ATLAS 3D TCAD. In this work, the Non-Equilibrium Green’s Function approach along with the self-consistent solution of Schrödinger’s equation and Poisson’s equation has been considered. The channel is taken to be lightly doped in the case of IM DM CGAA SiNW type of device. The effect of DM Gate work function engineering for SiNW channel of diameter 3 nm with gate oxide (SiO_2) the thickness of 0.8 nm on I_D , g_m , TGF, f_T , τ , FTP and R_CH has been studied. Moreover, a comparative study has been made between IMDM and JLDM CGAA SiNW devices with the above-mentioned parameters. For the JL device, the optimization of doping concentration is performed to get the same (i) ION current and (ii) threshold voltage (VTH) as the IM device. About 3.09 times and 21.89 times reduction in IOFF is seen for the same ION and VTH optimized devices respectively as compared to IM device. It has been found that DM Gate variation minimizes drain-induced barrier lowering (DIBL) in IM and JL devices. The JL SiNW showed much lower DIBL 16.46 mV/V, a near ideal SS 60 mV/dec, and higher I_ON/I_OFF current ratio 7.04 × 108 which is much better as compared to those reported in the literature for cylindrical gate all around (CGAA) devices. Also, it is found that the JL SiNW device performs better than IM in terms of SS, DIBL, I_ON/I_OFF , g_m, TGF, fT, τ , FTP and R_SD+CH .