FLOGEN Logo
In Honor of Nobel Laureate Dr. Avram Hershko
SIPS 2024 logo
SIPS 2024 takes place from October 20 - 24, 2024 at the Out of the Blue Resort in Crete, Greece

Honoree Banner
PROGRAM NOW AVAILABLE - CLICK HERE

More than 540 abstracts submitted from over 50 countries


Featuring many Nobel Laureates and other Distinguished Guests


Back

MULTISCALE CRYSTAL LATTICE CHEMISTRY FOR IMPROVING THERMOELECTRIC PERFORMANCE
In Chung1
1Seoul National University, Seoul, South Korea

PAPER: 351/SolidStateChemistry/Invited (Oral) OS
SCHEDULED: 16:05/Wed. 23 Oct. 2024/Ariadni A

ABSTRACT:

The introduction of foreign atoms or vacancies into crystal matrices forms atomic-level defects, giving rise to unique defect structures influenced by their coordination preferences and sizes relative to constituent atoms in the matrix. These defects can evolve into more complex structures like one-dimensional dislocations or nanostructures, each interacting uniquely with charge carriers and phonons, thereby significantly impacting the transport properties of bulk solids. Consequently, understanding the formation mechanisms of these defects is essential for developing highly predictable design principles and stabilizing desired defect structures within bulk crystals.

In this presentation, I will discuss our recent research on the deliberate design of multiscale defect structures across various types of crystal lattices. These structures enable independent control over crucial physical parameters that determine the thermoelectric figure of merit (ZT), such as carrier mobility, concentration, electrical conductivity, and Seebeck coefficient. Through this approach, we explore unconventional pathways to enhance ZT, promising significant advancements in thermoelectric materials.

REFERENCES:
[1] I. Chung* et al. Simultaneously engineering electronic and phonon band structures for high-performance n-type polycrystalline SnSe, Joule 2024, 8, 1520.
[2] I. Chung* et al. Engineering an atomic-level crystal lattice and electronic band structure for extraordinarily high average thermoelectric figure of merit in n-type PbSe, Energy Environ. Sci. 2023, 16, 3994.
[3] I. Chung* et al. Polycrystalline SnSe with a thermoelectric figure of merit greater than the single crystal. Nat. Mater. 2021, 20, 1378.