Trends on 3d Transition Metal Coordination on Monolayer MoS$_2$

TL;DR

This study investigates how 3d transition metals coordinate with monolayer MoS$_2$, revealing trends in bonding, charge transfer, and doping, which enhance understanding of single-atom functionalization for tailored properties.

Contribution

It combines theoretical and experimental approaches to elucidate the periodic trends and bonding nature of 3d transition metals on MoS$_2$, advancing the control of TMD surface functionalization.

Findings

Softer acids like Ni form more covalent bonds with MoS$_2$.

Harder acids like Cr tend to form more ionic bonds.

Ni induces n-type doping, Cu induces p-type doping.

Abstract

Two-dimensional materials (2DM) have attracted much interest due to their distinct optical, electronic, and catalytic properties. These properties can be by tuned a range of methods including substitutional doping or, as recently demonstrated, by surface functionalization with single atoms, increasing even further 2DM portfolio. Here we theoretically and experimentally describe the coordination reaction between MoS$_2$ monolayers with 3d transition metals (TMs), exploring the nature and the trend of MoS$_2$-TMs interaction. Density Functional Theory calculations, X-Ray Photoelectron Spectroscopy (XPS), and Photoluminescence (PL) point to the formation of MoS$_2$-TM coordination complexes, where the adsorption energy trend for 3d TM resembles the crystal-field (CF) stabilization energy for weak-field complexes. Pearson's theory for hard-soft acid-base and Ligand-field theory were applied to discuss the periodic trends on 3d TM coordination on the MoS$_2$ surface. We found that softer acids with higher ligand field stabilization energy, such as Ni$^{2+}$, tend to form bonds with more covalent character with MoS$_2$, which can be considered a soft base. On the other hand, harder acids, such as Cr$^{3+}$, tend to form bonds with more ionic character. Additionally, we studied the trends in charge transfer and doping observed in the XPS and PL results, where metals such as Ni led to an n-type of doping, while Cu functionalization results in p-type doping. Therefore, the formation of coordination complexes on TMD's surface is demonstrated to be a promising and effective way to control and to understand the nature of the single-atom functionalization of TMD.