Analytical Modeling of Double-Gate and Nanowire Junctionless ISFETs

In this article, we present a theoretical analysis of a junctionless (JL), ion-sensitive, field-effect-transistor (ISFET), self-consistently combining the electrochemical interaction between the semiconductor-insulator interface and the surrounding electrolyte medium. Incorporating charge-based core relationships for the nanowire (NW) and planar double gate (DG) JL FETs with basic relations governing the electrolyte-insulator proton exchanges, we predict the output characteristics of the NW and DG JL ISFETs with respect to pH for all the regions of operation. This hybrid charge-based approach of JL ISFETs is fully validated by COMSOL Multiphysics simulations without the need to introduce any fitting parameters. These developments are suitable for implementation in circuit simulators as well as for fast prototyping by tuning the technological parameters and estimate their impact on the device performances, including the electrolyte medium.

Analytical Modeling of Double-Gate and Nanowire Junctionless ISFETs

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Towards Scalable Electronics: Synthetic 2D Materials for Large-Area 2D Circuit Integration

Active Voltage Balancing with Seamless Integration into Dual Gate Driver for Series Connection of SiC MOSFETs

Strain relaxation and multidentate anchoring in n-type perovskite transistors and logic circuits