Vertical tunneling FET with Ge/Si doping-less heterojunction, a high-performance switch for digital applications.

A vertical tunneling field effect transistor composed of a doping-less tunneling heterojunction and an n+-drain is presented in this paper. Two highly-doped p+ silicon layers are devised to induce holes in an intrinsic source region. Due to employing a double gate configuration and Hafnium in the gate oxide, our proposed structure has an optimized electrostatic control over the channel. We have performed all the numerical simulations using Silvaco ATLAS, calibrated to the verified data of a device with the similar working principle. The impact of the wide range of non-idealities, such as trap-assisted tunneling, interface trap charges, and ambipolar conduction, is thoroughly investigated. We have also evaluated the impact of negative capacitance material to further improve our device switching characteristics. Introducing both n-channel and p-channel devices, and employing them into a 6T SRAM circuit, we have investigated its performance in terms of parameters like read and write SNM. The FOMs such as Ion = 34.4 µA/µm, Ion/Ioff = 7.17 × 107, and fT = 123 GHz show that our proposed device is a notable candidate for both DC and RF applications.

Impact of trap-related non-idealities on the performance of a novel TFET-based biosensor with dual doping-less tunneling junction.

This article presents a novel dielectric-modulated biosensor based on a tunneling field-effect transistor. It comprises a dual doping-less tunneling junction that lies above an n+ drain region. By employing the wet-etching technique, two cavities are carved in the gate dielectric, and with the entry of various biomolecules into the cavities, the electrostatic integrity of the gate changes, accordingly. Numerical simulations, carried out by the Silvaco ATLAS device simulator, show that including trap-assisted tunneling significantly modulate the biosensor's main parameters, such as on-state current, subthreshold swing, and transconductance and their corresponding sensitivities. We also evaluate the effect of semi-filled cavities on our proposed biosensor's performance with various configurations. The FOMs like Ion/Ioff = 2.04 × 106, [Formula: see text]=1.48 × 105, and [Formula: see text]=0.61 in the presence of TAT show that our proposed biosensor has a promising performance.