# Compact Modeling of MOSFET I-V Characteristics and Simulation of   Dose-Dependent Drain Currents

**Authors:** G. I. Zebrev, V. V. Orlov, A. S. Bakerenkov, V. A. Felitsyn

arXiv: 1702.06454 · 2017-02-22

## TL;DR

This paper introduces a compact MOSFET model capable of accurately simulating I-V characteristics and dose-dependent drain currents in irradiated transistors across various operation modes and temperatures, suitable for integration into standard CAD tools.

## Contribution

A novel compact model for irradiated MOSFETs, including a rebound effect, compatible with BSIM, enabling accurate simulation of dose effects in scaled circuits.

## Key findings

- Successfully modeled dose-dependent drain currents up to 1Grad irradiation.
- Compatible with standard BSIM parameters and CAD tools.
- Accurately describes I-V characteristics across operation modes and temperatures.

## Abstract

We have presented a compact MOSFET model, which allows us to describe the I-V characteristics of irradiated long-channel and short-channel transistors in all operation modes at different measurement temperatures and interface trap densities. The model allows simulating of the off-state and the on-state drain currents of irradiated MOSFETs based on an equal footing. Particularly, a novel compact model of the rebound effect in n-MOSFETs was employed for simulation of the total dose dependencies of drain currents in the highly scaled 60 nm node circuits irradiated up to 1Grad. Compatibility of the model parameter set with BSIM and a single closed form of the model equation imply the possibility of its easy implementation into the standard CAD tools.

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Source: https://tomesphere.com/paper/1702.06454