Environment-insensitive and gate-controllable photocurrent enabled by bandgap engineering of MoS2 junctions
Fu-Yu Shih, Yueh-Chun Wu, Yi-Siang Shih, Ming-Chiuan Shih, Po-Hsun Ho,, Chun-Wei Chen, Yang-Fang Chen, Ya-Ping Chiu, and Wei-Hua Wang

TL;DR
This study demonstrates that the short-circuit photocurrent in MoS2 junctions remains stable across various gaseous environments, offering a new approach for designing robust 2D-material-based optoelectronic devices.
Contribution
It introduces a method to achieve environment-insensitive photocurrent in MoS2 junctions through bandgap engineering, bypassing the need for encapsulation.
Findings
Short-circuit photocurrent is insensitive to environmental gases.
Photocurrent with bias depends on gaseous environment.
Built-in electric field drives stable photocurrent.
Abstract
Two-dimensional (2D) materials are composed of atomically thin crystals with an enormous surface-to-volume ratio, and their physical properties can be easily subjected to the change of the chemical environment. Encapsulation with other layered materials, such as hexagonal boron nitride, is a common practice; however, this approach often requires inextricable fabrication processes. Alternatively, it is intriguing to explore methods to control transport properties in the circumstance of no encapsulated layer. This is very challenging because of the ubiquitous presence of adsorbents, which can lead to charged-impurity scattering sites, charge traps, and recombination centers. Here, we show that the short-circuit photocurrent originated from the built-in electric field at the MoS2 junction is surprisingly insensitive to the gaseous environment over the range from a vacuum of 1X10^(-6) Torr…
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Taxonomy
Topics2D Materials and Applications · MXene and MAX Phase Materials · Graphene research and applications
