not-yet-known not-yet-known not-yet-known unknown In this study, a comprehensive investigation of a short channel Heterojunction Hetero-Dielectric Graded Silicon-Germanium Channel Double Gate Tunnel FET (HJ-HD-GSGC-DG-TFET) is performed to justify improvement of its various Figure of Merits (FOM) in comparison to its four counterparts. A physics-based explicit analytical model for surface potential profile, drain current, and capacitance is created utilizing bandgap engineering techniques of a graded silicon-germanium channel (Si(1-x)Gex) with a pure germanium source and a lightly doped silicon drain operating at a low supply voltage (VDS) of 0.8 V in a 40 nm technology node. The effects of trap assisted tunneling, source depletion with fringing field effect, and mobile charges in intrinsic channel segments are taken into account while developing analytical models, and the results are consistent with TCAD simulations. The proposed device achieved the most important Figure of Merits (FoM) such as an increase in ON current to 3.74 x 10-4 A/ μm with a steeper subthreshold swing of 28.3 mV/decade, a low threshold voltage of 0.42 V, a moderate on-off current ratio of 109 order, a maximum transconductance of 0.82 mS, a cut off frequency of 13.52 GHz, a gain band width (GBW) of 19.8 GHz and reduced power dissipation, making the device most promising for low power integrated circuits.

Due to limitations of Silicon, Transition metal dichalcogenides (TMD) based biosensors are popular in the recent times. In TMD family, Molybdenum telluride (MoTe2) is being studied a lot for different biosensing application. However, for DNA detection using TMD based DMFET, the effect of the electrical variations in DNA has not been studied before. Also, the impact of DNA-Electrode interaction on transducer level of DMFET is yet to be studied. In this article, we have proposed a Molybdenum telluride (MoTe2) based Accumulation Mode Field Effect Transistor (AMFET) for possible dielectric modulated biosensing application. The study is focused on DNA detection including the electric variations of DNA due to surface interaction. We have done a circuit level analysis of the proposed structure for having deeper insights into its performance under various DNA orientations in the nanogap. We have also presented a benchmarking to highlight the superior sensitivity of the proposed structure (∆Vth = 700mV at K = 8). The impact of back-gate bias is also included. We have obtained significant variation of threshold voltage shift for different orientation in the proposed structure suggesting strong impact of electrical variations in DNA in biosensing performance of MoTe2 AMFET.