High Photoresponsivity and Short Photo Response Times in Few-Layered WSe$_2$ Transistors

TL;DR

This study demonstrates that tri-layered WSe₂ transistors exhibit high photoresponsivity and rapid response times, surpassing more complex structures, due to minimized substrate interactions in a simple architecture.

Contribution

It reveals that few-layered WSe₂ transistors achieve high photoresponsivity and fast response times with simple design, outperforming complex heterostructures.

Findings

Photoresponsivity up to 7 A/W under white light.

Photo response times around 10 microseconds.

High hole mobilities exceeding 350 cm²/Vs.

Abstract

Here, we report the photoconducting response of field-effect transistors based on three atomic layers of chemical vapor transport grown WSe$_2$ crystals mechanically exfoliated onto SiO$_2$. We find that tri-layered WSe$_2$ field-effect transistors, built with the simplest possible architecture, can display high hole mobilities ranging from 350 cm$^2$/Vs at room temperature (saturating at a value of ~500 cm$^2$/Vs below 50 K) displaying a strong photocurrent response which leads to exceptionally high photo responsivities up to 7 A/W under white light illumination of the entire channel for power densities p < 10$^2$ W/m$^2$. Under a fixed wavelength of $\lambda$ = 532 nm and a laser spot size smaller than the conducting channel area we extract photo responsitivities approaching 100 mA/W with concomitantly high external quantum efficiencies up to ~ 40 % at room temperature. These values surpass values recently reported from more complex architectures, such as graphene and transition metal dichalcogenides based heterostructures. Also, tri-layered WSe$_2$ photo-transistors display photo response times in the order of 10 microseconds. Our results indicate that the addition of a few atomic layers considerably decreases the photo response times, probably by minimizing the interaction with the substrates, while maintaining a very high photo-responsivity.