Control of MXenes’ electronic properties through termination and intercalation

• Published in: Nature communications Vol. 10; no. 1; pp. 522 - 10
• Main Authors: Hart, James L., Hantanasirisakul, Kanit, Lang, Andrew C., Anasori, Babak, Pinto, David, Pivak, Yevheniy, van Omme, J. Tijn, May, Steven J., Gogotsi, Yury, Taheri, Mitra L.
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 31.01.2019; Nature Publishing Group; Nature Portfolio
• Subjects: 147/143; 639/301/299; 639/301/357/1018; 639/301/357/995; Absorption; Chromophores; Conductivity; Electronic properties and materials; Energy storage; Humanities and Social Sciences; Internal conversion; Materials for energy and catalysis; MATERIALS SCIENCE; multidisciplinary; MXenes; Organic chemistry; Photosynthesis; Science; Science & technology - other topics; Science (multidisciplinary); Selectivity; Soft x rays; Surface chemistry; Two-dimensional materials; X-rays
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-018-08169-8

MXenes are an emerging family of highly-conductive 2D materials which have demonstrated state-of-the-art performance in electromagnetic interference shielding, chemical sensing, and energy storage. To further improve performance, there is a need to increase MXenes’ electronic conductivity. Tailoring the MXene surface chemistry could achieve this goal, as density functional theory predicts that surface terminations strongly influence MXenes' Fermi level density of states and thereby MXenes’ electronic conductivity. Here, we directly correlate MXene surface de-functionalization with increased electronic conductivity through in situ vacuum annealing, electrical biasing, and spectroscopic analysis within the transmission electron microscope. Furthermore, we show that intercalation can induce transitions between metallic and semiconductor-like transport (transitions from a positive to negative temperature-dependence of resistance) through inter-flake effects. These findings lay the groundwork for intercalation- and termination-engineered MXenes, which promise improved electronic conductivity and could lead to the realization of semiconducting, magnetic, and topologically insulating MXenes. Two-dimensional transition metal carbides and nitrides (MXenes) have emerged as highly conductive and stable materials, of promise for electronic applications. Here, the authors use in situ electric biasing and transmission electron microscopy to investigate the effect of surface termination and intercalation on electronic properties.