Seminar "2D thermoelectric materials: Role of the lattice thermal conductivity"

Title: 2D thermoelectric materials: Role of the lattice thermal conductivity

Abstract:

The presentation gives an overview of ab-initio calculations addressing the thermoelectric performance of MXenes. Specific examples include a comparison of Ti₂CO₂, Zr₂CO₂, and Hf₂CO₂ in order to evaluate the role of the metal atom. The lattice thermal conductivity is demonstrated to grow along the series Ti-Zr-Hf in the temperature range 300-700 K, resulting in the highest figure of merit in the case of Ti₂CO₂. Flat conduction bands promote the thermopower in the case of n-doping. Functionalization effects are studied for Sc₂C, which is semiconducting for various functional groups, including O, F, and OH. The lowest lattice thermal conductivity is found for OH functionalization. Despite a relatively low thermopower, Sc₂C(OH)₂ therefore and due to a high electrical conductivity can be interesting for intermediate-temperature thermoelectric applications.

Biography:

Dr. Schwingenschlögl is a Professor of Materials Science & Engineering at King Abdullah University of Science and Technology (KAUST). His research interests in condensed matter physics and first-principles materials modeling focus on two-dimensional materials, interface and defect physics, correlated materials, thermoelectric materials, metal-ion batteries, nanoparticles, and quantum transport. Dr. Schwingenschlögl joined KAUST as founding faculty member in 2008, having previously worked at the International Center of Condensed Matter Physics in Brasilia, Brazil, and the Universität Augsburg in Germany.