WIN - Distinguished Lecture: Yury Gogotsi

The Waterloo Institute for Nanotechnology (WIN) is pleased to present a Distinguished Lecture by Yury Gogotsi, a distinguished professor in the Department of Materials Science and Engineering at Drexel University. 

Please note, in-person tickets for this event have SOLD OUT. Please do not come in-person to QNC 1501 unless you have already reserved your ticket. We currently have two options available to watch Professor Gogotsi's lecture:

Watch via Zoom: WIN has created an online option via Zoom. Pre-registration for this option is required. Please register below!

Watch in-person - overflow seating: If you arrive in-person for the lecture without an Eventbrite ticket, you will be re-directed to overflow seating in QNC 3402 to watch the lecture via Zoom.

The Fascinating World of Two-Dimensional Carbides and Nitrides (MXenes)

Abstract

Discovery of new materials provides moments of inspiration and shifts in understanding, shaping the dynamic field of materials science. Following the graphene breakthrough, many other 2D materials emerged. Although many of them remain subjects of purely academic interest, others have jumped into the limelight due to their attractive properties, which have led to practical applications. Among the latter are 2D carbides and nitrides of transition metals known as MXenes [1]. The family of MXenes has been expanding rapidly since the discovery of Ti₃C₂ in 2011. More than 30 different stoichiometric MXenes have been reported, and the structure and properties of numerous other MXenes have been predicted. Moreover, the availability of solid solutions on M and X sites, multi-element high-entropy MXenes, control of surface terminations, and the discovery of out-of-plane ordered double-M o-MXenes (e.g., Mo₂TiC₂), as well as in-plane ordered i-MAX phases and their i-MXenes offer a potential for producing dozens of new distinct structures. This presentation will describe the state of the art in the manufacturing of MXenes, their delamination into single-layer 2D flakes and assembly into films, fibers and 3D structures. 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. In particular, the interaction of MXenes with electromagnetic waves can be controlled via their composition and structure. Many MXenes offer high electronic conductivity and outstanding electromagnetic interference shielding. They can also be used in telecommunication, energy, medical and electronic device applications.

Biography