Plasmon-assisted MXene grafting: tuning of surface termination and stability enhancement

The properties of MXenes, new generation of 2D materials, are determined by the surface terminations, which depends on flake preparation method. Changing the surface termination chemical groups can significantly modify the MXene flake properties and functionality. However, the common methods of MXene flake surface chemistry tuning require high-energy treatments and often lead to flake damage. In this work, we propose a plasmon-assisted chemical transformation for tuning the surface chemistry and termination of MXene flakes. The plasmon resonance was directly excited on MXene flakes and induced the generation of highly reactive radicals from electrostatically absorbed iodonium salt cations, leading to immediate grafting of the created radicals to the flake edges and basal planes. We used bis-CF3-substituted iodonium salts, and subsequent analysis of the Ti3C2T (x) MXene flake surface composition indicated decreases in the total oxygen concentration and oxidized titanium with a simultaneous increase in the fluorine surface concentration, which was related to -C6H3(CF3)(2) moiety attachment. The ability to substitute the hydrophilic oxygen-containing groups with hydrophobic and oleophilic -CF3 groups containing functional groups allows us to create a stable suspension of a MXene in nonpolar organic solvents and prepare a superhydrophobic, water-repellent and oxidation-stable conductive MXene coating.

Automated summary

The properties and functionality of MXene are determined by the surface terminations, and this study proposes a plasmon-assisted chemical transformation method to modify the surface chemistry and termination of MXene flakes. By using bis-CF3-substituted iodonium salts, the hydrophilic oxygen-containing groups on MXene flakes were successfully substituted with hydrophobic and oleophilic -CF3 groups, resulting in a superhydrophobic, water-repellent, and oxidation-stable conductive MXene coating.