Humidity-enhanced NO$_2$ gas sensing using atomically sharp edges in multilayer MoS$_2$

TL;DR

This study demonstrates that atomically sharp edges in multilayer MoS₂ significantly improve NO₂ gas sensing performance, especially under high humidity and UV illumination, enabling detection at sub-ppb levels with high sensitivity and selectivity.

Contribution

The paper introduces a humidity-tolerant, UV-enhanced NO₂ sensing method using atomically precise MoS₂ edges, advancing nanostructured 2D materials for environmental monitoring.

Findings

33-fold increase in response at 2.5 ppb NO₂ under humidity and UV light

Detection limit as low as 4 ppt NO₂

Enhanced sensing performance confirmed by first-principles calculations

Abstract

Ambient humidity poses a significant challenge in the development of practical room temperature NO$_2$ gas sensors. Here, we employ atomically precise zigzag edges in multilayer MoS$_2$, fabricated using electron beam lithography and anisotropic wet etching, to achieve highly sensitive and selective gas sensing performance that is humidity-tolerant at elevated temperatures and humidity-enhanced at room temperature under ultraviolet illumination. Notably, exposure to 2.5 parts per billion (ppb) NO$_2$ at 70% relative humidity under ultraviolet illumination and at room-temperature resulted in a 33-fold increase in response and a 6-fold faster recovery compared to 0% relative humidity, leading to response values exceeding 1100%. The optimized samples demonstrated a theoretical detection limit ranging from 4 to 400 parts per trillion (ppt) NO$_2$. The enhanced NO$_2$ sensing capabilities of MoS$_2$ edges have been further confirmed through first-principles calculations. Our study expands the applications of nanostructured MoS$_2$ and highlights its potential for detecting NO$_2$ at sub-ppb levels in complex scenarios, such as high humidity conditions.