Two-Dimensional Carbides and Nitrides (MXenes) Challenge Graphene


Two-dimensional (2D) materials with a thickness of a few nanometers or less can be used as single sheets, or as building blocks, due to their unique properties and ability to assemble into a variety of structures. Graphene is the best-known example, but several other elemental 2D materials (silicene, borophene, etc.) have been discovered. Numerous compounds, ranging from clays to boron nitride (BN) and transition metal dichalcogenides, have been produced as 2D sheets. By combining various 2D materials, unique combinations of properties can be achieved which are not available in any bulk material. The family of 2D transition metal carbides and nitrides (MXenes) has been expanding rapidly since the discovery of Ti3C2 in 2011 [1]. Approximately 30 different MXenes have been synthesized, and the structure and properties of numerous other MXenes have been predicted using density functional theory (DFT) calculations [2]. Moreover, the availability of solid solutions on M and X sites, control of surface terminations, and the discovery of ordered double-M MXenes (e.g., Mo2TiC2) offer the potential for synthesis of dozens of new distinct structures.

This presentation will describe the synthesis of MXenes by selective etching of layered ceramic precursors, including various MAX phases. Delamination into single-layer 2D flakes and assembly into films and 3D structures, as well as their properties will be discussed. Synthesis-Structure-Properties relations of MXenes will be addressed on the example of Ti3C2.

The versatile chemistry of the MXene family renders their properties tunable for a large variety of applications [3]. Oxygen or hydroxyl- terminated Menes, such as Ti3C2O2, have been shown to have redox capable transition metals layers on the surface and offer a combination of high electronic conductivity with hydrophilicity, as well as fast ionic transport [4].  This, among many other advantageous properties, makes the material family promising candidates for energy storage and related electrochemical applications [5], but applications in plasmonics, electrocatalysis, biosensors, water purification/ desalination and other fields are equally exciting. In particular, capacitive deionization and membrane desalination and purification will be addressed.


(Location: Monroe Hall Rm 110)
3:30PM | Monroe Hall Room 110
Wednesday, April 17, 2019
Dr. Yury Gogotsi
Drexel University
Professor Sen Zhang