Abstract:
Low-temperature processing of high-capacitance metal oxide-based dielectrics by solution-based methods and their application in developing low-voltage carbon-based transistors may enable next-generation low-cost, power-efficient, flexible and transparent electronics. In this work, a high-capacitance alox film was developed at a relatively low annealing temperature of ⁓200 °c from its spin-coated precursor solution. Its application in both low-voltage n-as well as p-channel field-effect transistors (fets) was demonstrated, gaining feedback on microstructure and dielectric properties by using x-ray diffraction, x-ray photoelectron spectroscopy, atomic force microscopy, as well as impedance and current-voltage measurements. The operating voltage of both n-channel fets based on a semiconducting polymer as well as p-channel fets with polymer-sorted semiconducting (6,5) single-walled carbon nanotube (s-swcnt) networks was found to be within 1.5 v range. This work demonstrates the viability of low-temperature alox dielectrics in low-voltage carbon-based electronics towards low-power distributed, portable and wearable applications. © 2022 elsevier b.v.