Performance enhancement of recessed silicon channel double gate junctionless field-effect-transistor using TCAD tool

In this paper, we propose an n-type double gate junctionless field-effect-transistor using recessed silicon channel. The recessed silicon channel reduces the channel thickness between the underlap regions, results in lowering the number of charge carriers in the silicon channel, and therefore, diminishing the OFF-current in the device. The proposed device shows similar electrical characteristics with improved transconductance, as compared to the conventional double gate junctionless field-effect-transistor. The effect of channel length scaling on the performance have been investigated, and it has been found that the recessed junctionless device shows higher ON-to-OFF current ratio, lower subthreshold swing and better immunity against the short channel effects, namely threshold voltage roll-off and drain-induced-barrier-lowering. For a channel length of 20 nm the OFF-current of the order of 1.20?×?10^–14 A/µm, ON-to-OFF current ratio of the order of 6.01?×?10¹⁰, subthreshold swing of the value of 67 mV/dec, and DIBL of 37.8 mV V^?1 has been achieved with the proposed junctionless device, in comparison of conventional double gate junctionless FET. The performance of proposed device with respect to the variations in depth and length of recessed silicon area, has also been presented as a roadmap for further tuning of its electrical behaviour. Comparatively, steeper DC transfer characteristics and improved rail-to-rail swing in transient behaviour has been reported with the designed complementary metal–oxide–semiconductor inverter, based on recessed double gate junctionless FET. The proposed recessed silicon channel double gate junctionless field-effect-transistor has been simulated using TCAD tool.