Temperature Dependent Characteristics and Electrostatic Threshold Voltage Tuning of Accumulated Body MOSFETs

TL;DR

This study investigates the temperature-dependent electrical characteristics of accumulated body MOSFETs and demonstrates electrostatic threshold voltage tuning via side-gate biasing, enabling precise control over device behavior across a wide temperature range.

Contribution

It provides detailed analysis of temperature effects on subthreshold slope, DIBL, and threshold voltage, and introduces a method for electrostatic Vt tuning using side-gate biasing.

Findings

Subthreshold slope decreases from 115 to 36 mV/dec as temperature drops from 400 K to 100 K.

DIBL reduces by approximately 10 mV/V per 100 K temperature decrease.

Threshold voltage increases from 0.42 V to 0.61 V with decreasing temperature.

Abstract

Narrow-channel accumulated body nMOSFET devices with p-type side-gates surrounding the active area have been electrically characterized between 100 and 400 K with varied side-gate biasing (Vside). The subthreshold slope (SS) and drain induced barrier lowering (DIBL) decrease and threshold voltage (Vt) increases linearly with reduced temperature and reduced side-gate bias. Detailed analysis on a 27 nm x 78 nm (width x length) device show SS decreasing from 115 mV/dec at 400 K to 90 mV/dec at 300 K and down to 36 mV/dec at 100 K, DIBL decreasing by approximately 10 mV/V for each 100 K reduction in operating temperature, and Vt increasing from 0.42 V to 0.61 V as the temperature is reduced from 400 K to 100 K. Vt can be adjusted from ~ 0.3 V to ~ 1.1 V with ~0.3 V/V sensitivity by depletion or accumulation of the body of the device using Vside. This high level of tunability allows electronic control of Vt and drive current for variable temperature operation in a wide temperature range with extremely low leakage currents (< 10-13 A).