Adsorption and dissociation of NO2 on MoS2 doped with p-block elements

•Se doping has virtually no impact on the adsorption of NO2 on MoS2.•Cl doping favors the same adsorption as the pristine sheet, but enhances the binding.•Si, P, and Ge doping promotes strong bonding of oxygen-dopant and nitrogen-dopant.•In some cases the oxygen-dopant interaction is strong enough t...

Full description

Saved in:
Bibliographic Details
Published inSurface science Vol. 712; p. 1
Main Authors Szary, Maciej J., Bąbelek, Jakub A., Florjan, Dominik M.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.10.2021
Elsevier BV
Subjects
Accumulation
Acid rain
Adsorption
Catalysis
Charge transfer
Chemical compounds
Density functional theory
Dissociation
Doping
Greenhouse effect
Layered materials
Molybdenum disulfide
MoS[formula omitted]
Nitrogen dioxide
NO[formula omitted]
Substrates
Surface chemistry
NO2
Density functional theory
MoSMoS2
Dissociation
Adsorption
Doping
Online AccessGet full text

Cover

More Information
Summary:•Se doping has virtually no impact on the adsorption of NO2 on MoS2.•Cl doping favors the same adsorption as the pristine sheet, but enhances the binding.•Si, P, and Ge doping promotes strong bonding of oxygen-dopant and nitrogen-dopant.•In some cases the oxygen-dopant interaction is strong enough to reduce NO2 to NO.•Si, P, Cl and Ge doping enhances the electron transfer to the molecule of NO2. [Display omitted] Nitrogen dioxide (NO2) is a chemical compound produced in large amounts as a byproduct of combustion in vehicles and industrial processes. In its gas form, it is harmful to both human health and the environment causing acid rain, greenhouse effects, and a variety of respiratory symptoms. Hence, significant effort has been put into its detection and removal including studies on low-dimensional layered materials. Those have shown that molecules of NO2 have a good affinity for surfaces of molybdenum disulfide (MoS2). This allows for NO2 detection, however, the interaction is too weak for its effective accumulation or subsequent catalysis. Consequently, this work investigates, employing density functional theory, doping of MoS2 for enhanced NO2 adsorption, and the extent to which it affects the molecule. The results show that the strength of molecule-substrate interaction depends on the changes in the orbital population of the dopant. This results in different adsorption configurations with varying energies and molecule-substrate charge transfers. The changes allow Cl-MoS2 to be more suitable for detection, and Ge-MoS2 accumulation of NO2. Also, due to the interaction strength, the Si and P doped monolayers facilitate dissociation of NO2 into NO. Thus, tuning the potential of MoS2 for surface catalysis.
ISSN:0039-6028
1879-2758
DOI:10.1016/j.susc.2021.121893