Molecular Cross-linking of MXenes: Tunable Interfaces and Chemiresistive Sensing

Abstract: MXenes, a family of 2D transition metal compounds, have emerged as promising materials due to their unique electronic properties and tunable surface chemistry. However, the translation of these nanoscale properties into macroscopic devices is constrained by suitable cross-linking strategies that enable both processability and controlled inter flake charge transport. Herein, we demonstrate the tunability of interfaces and the inter-layer spacing between Ti$_3$C$_2$T$_x$ MXene flakes through molecular cross-linking with homologous diamines. Oleylamine was first used to stabilize Ti$_3$C$_2$T$_x$ MXene in chloroform, followed by diamine-mediated cross-linking to precisely tune interlayer spacing. Grazing incidence X-ray scattering (GIXRD/GIWAXS) confirmed the correlation between ligand chain length and inter-layer spacing, which was further supported by Density Functional Theory (DFT) calculations. Furthermore, we investigated the charge transport properties of thin films consisting of these diamine-crosslinked Ti$_3$C$_2$T$_x$ MXenes and observed a strong dependence of the conductivity on the interlayer spacing. Finally, we probed chemiresistive vapor sensing properties of the MXene composites and observed a pronounced sensitivity and selectivity towards water vapor, highlighting their potential for use in humidity sensors. Insights into the molecular cross-linking of MXenes to form a hybrid inorganic/organic system and its implications for charge transport, this study opens avenues for developing next-generation MXene-based electronic devices.