Theoretical Study of ZnS Monolayer Adsorption Behavior for CO and HF Gas Molecules

Overview

Journal ACS Omega

Publisher American Chemical Society

Specialty Chemistry

Date 2022 Nov 17

PMID 36385877

Authors

Lalmuan Chhana

Bernard Lalroliana

Ramesh Chandra Tiwari

Bhanu Chettri

Lalrinthara Pachuau

Shivraj Gurung

Lalmuanpuia Vanchhawng

Dibya Prakash Rai

Lalhriat Zuala

Ramakrishna Madaka

Affiliations

Soon will be listed here.

Abstract

Adsorption of carbon monoxide (CO) and hydrogen fluoride (HF) gas molecules on a ZnS monolayer with weak van der Waals interactions is studied using the DFT + method. From our calculation, the ZnS monolayer shows chemisorption with CO ( = -0.96 eV) and HF ( = -0.86 eV) gas molecules. Bader charge analysis shows that charge transfer is independent of the binding environment. A higher energy barrier for CO when migrating from one optimal site to another suggests that clustering may be avoided by the introduction of multiple CO molecules upon ZnS, while the diffusion energy barrier (DEB) for HF suggests that binding may occur more easily for HF gas upon the ZnS ML. Adsorption of the considered diatomic molecule also results in a significant variation in effective mass and therefore can be used to enhance the carrier mobility of the ZnS ML. Additionally, the calculation of recovery time shows that desirable sensing and desorption performance for CO and HF gas molecules can be achieved at room temperature (300 K).

Citing Articles

Highly sensitive sensing of CO and HF gases by monolayer CuCl.

Pervaiz S, Saeed M, Khan S, Asghar B, Saeed Y, Elansary H RSC Adv. 2024; 14(23):16284-16292.

PMID: 38774614 PMC: 11106810. DOI: 10.1039/d4ra01519c.

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