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DFT Study on the Janus ZrSSe Monolayer for Its Potential Application in NO Gas Sensing

Mengyang Zhang, Jianjun Xia, Gang Guo, Gencai Guo, Landong Xiao, Manqi You, Siwei Luo, Qiong Chen, Chaobo Luo, Chaoyu He, Chao Tang

2024Langmuir21 citationsDOI

Abstract

The growth of industry has resulted in increased global air pollution, necessitating the urgent development of highly sensitive gas detectors. In this work, the adsorption of the Janus ZrSSe monolayer for CO, CO 2, NH 3, NO, NO 2, and O 2 was studied by first-principles calculations. First, the stability of the ZrSSe monolayer is confirmed through calculations of cohesive energy and AIMD simulations. Furthermore, the calculations indicate that the Se layer exhibits higher selectivity and sensitivity toward gas molecules compared to the S layer. Specifically, among the gases adsorbed on the Se layer, NO has the shortest adsorption distance (1.804 Å), the lowest adsorption energy (−0.424 eV), and the greatest electron transfer (0.098 e). Additionally, density of states analysis reveals that adsorption of NO, NO 2, and O 2 on the Janus ZrSSe monolayer can induce a transition from a nonmagnetic to a magnetic state. The adsorption of NO not only alters the magnetic state but also induces a transition from a semiconductor to metal, which is highly advantageous for gas sensing applications. There results suggest that the Janus ZrSSe monolayer has the potential to serve as a highly sensitive detector for NO gas.

Topics & Concepts

MonolayerJanusAdsorptionNanotechnologyChemistryMaterials sciencePhysical chemistry2D Materials and ApplicationsMXene and MAX Phase MaterialsAdvanced Thermoelectric Materials and Devices
DFT Study on the Janus ZrSSe Monolayer for Its Potential Application in NO Gas Sensing | Litcius