Electrical analysis of hysteresis in solution processed silicon nanowire field effect transistors

TL;DR

This study investigates hysteresis in solution-processed silicon nanowire FETs, identifying interface traps as a key factor and demonstrating a significant reduction in hysteresis using a fluoropolymer dielectric.

Contribution

It provides a detailed analysis of interface trap effects on hysteresis and introduces a solution processable fluoropolymer dielectric to mitigate this issue.

Findings

Hysteresis up to 40V is mainly due to hole traps at the nanowire/SiO2 interface.

Using Cytop dielectric reduces hysteresis to 2.5V.

Surface trap density is significantly lower with Cytop dielectric.

Abstract

Silicon nanowires (Si NW) are ideal candidates for solution processable field effect transistors (FETs). The interface between the nanowire channel and the gate dielectric plays a crucial role in the FET performance, and it can be responsible for unwanted effects such as hysteresis of the I-V characteristics due to threshold voltage shift when the gate voltage is applied. Using gate-voltage bias stress measurements we show that a large hysteresis of up to 40V in Si NW FETs with SiO2 dielectric is mainly due to the holes traps at the nanowire/SiO2 interface. An approach for reducing this hysteresis to just 2.5V using solution processable fluoropolymer dielectric Cytop in the top-gate configuration is demonstrated. Experimental results suggest that the density of surface traps in Si nanowire transistors is dictated mainly by the nature of the dielectric layer. The influence of the gate dielectric was studied by assessing the field effect transport behaviour of a representative double gate FETs based on SiO2 bottom dielectric and top Cytop dielectric layer. Such devices were characterised, revealing an order of magnitude higher hole traps density at the nanowire/SiO2 interface (1x10^13cm-2) compared to that of nanowire/fluoropolymer interface (7.5x10^11cm-2).