Surface Reduction Boosts Free Electron Concentration in MXene for Enhanced Photothermal Performance

TL;DR

This paper introduces a sodium-mediated surface reduction method to significantly enhance the free electron concentration and photothermal efficiency of MXene materials, enabling advanced applications like antibacterial wound dressings.

Contribution

The study presents a novel reduction strategy that increases electron density and conductivity in MXenes, leading to record photothermal performance and broad application potential.

Findings

Electron concentration increased by 4.92-fold.

Photothermal conversion efficiency reached 92.36%.

Demonstrated effective antibacterial wound dressing.

Abstract

The photothermal properties of MXenes originate from their high free electron concentration, which drives localized surface plasmon resonance (LSPR). However, their intrinsic electron concentration is limited by suboptimal d-orbital occupancy, while electronegative surface terminations actively deplete free electrons through orbital-selective withdrawal. Herein, we report a sodium (Na)-mediated surface reduction strategy in molten salts to transform Ti3C2Clx into electronically tunable Ti3C2. Specifically, Na atoms remove -Cl terminations to eliminate electron withdrawal and simultaneously inject electrons into the MXene lattice via a reduction reaction. This dual effect saturates Ti 3d-orbital vacancies while reducing surface coordination sites, achieving an increase in carrier concentration to 4.92-fold, an increase in mobility to 2.63-fold, and an enhancement in conductivity to 12.96-fold. Consequently, the optimized reduced MXene achieves a record photothermal conversion efficiency of 92.36% under 808 nm laser irradiation. As a proof-of-concept, a photothermal antibacterial woundplast with ultralow MXene content demonstrates a 91.39% bacterial kill rate. This work not only shows an effective way to tune the photothermal properties of MXenes but also inspires applications that require high electron concentration, such as energy storage, sensors, and electromagnetic interference shielding.