Transition metal atom adsorption on the titanium carbide MXene: Trends across the periodic table for the bare and O-terminated surfaces


MXenes are a family of two-dimensional materials of great interest due to their unique properties, e.g., adjustability based on changes in their composition, structure, and surface functionality, which grant MXenes a variety of applications. One way of changing the catalytic effect of MXenes consists of adsorbing isolated metallic elements, such as transition metals (TMs), onto their surface, leading to the formation of single-atom catalysts. Herewith, the adsorption behavior of 31 TMs on the surface of two titanium carbide MXenes, viz. Ti2C and Ti2CO2, is analyzed by means of density-functional theory (DFT) calculations. We find that the oxygen surface termination causes most of the TM atoms to adsorb on a hollow site above a carbon atom, whereas on bare Ti2C, the adsorption preference follows a pattern related to groups of the periodic table. The interaction between the TM atoms and the surface of both Ti2C and Ti2CO2 is strong, as demonstrated by the calculated adsorption energies, which range between about -1 and -9 eV on either surface. Upon adsorption on Ti2CO2, electrons are transferred from the adatom to the MXene surface, whereas on Ti2C, the only TM atoms for which this happens are the ones in group 3 of the periodic table. All the other transition metal atoms become negatively charged after adsorption on Ti2C. On the oxygen-covered MXene, stronger adsorptions are accompanied by higher charge transfers. The energy barriers for TM adatom diffusion on Ti2C are very small, meaning that the adatoms can move rather freely along it. On Ti2CO2, however, higher diffusion barriers were found, many being above 1 eV, which suggests that the oxygen termination layer blocks the diffusion. On both surfaces, the highest diffusion barriers were found to correspond to the TM elements which adsorb most strongly.




Materials Science


Rocha, H; Gouveia, JD; Gomes, JRB

nossos autores


This work was developed within the scope of the project CICECO-Aveiro Institute of Materials, Grants No. UIDB/50011/2020, No. UIDP/50011/2020, and No. LA/P/0006/2020, financed by national funds through the FCT/MEC (PIDDAC). We are also thankful to Fundacao para a Ciencia e a Tecnologia (FCT IP) for the computational resources granted in the framework of Project Ref. No. 2021.09799.CPCA by the FCT/CPCA/2021/01 Call for Advanced Computing Projects.

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