APS March Meeting 2017
Volume 62, Number 4
Monday–Friday, March 13–17, 2017;
New Orleans, Louisiana
Session C34: Thermal and Thermoelectric Transport - Theory and Modeling
2:30 PM–5:30 PM,
Monday, March 13, 2017
Room: 297
Sponsoring
Units:
DMP GERA DCOMP
Chair: Marco Fornari
Abstract ID: BAPS.2017.MAR.C34.7
Abstract: C34.00007 : Phonon Scattering in Thermoelectrics: Thermal Transport, Strong Anharmonicity, and Emergent Quasiparticles*
3:42 PM–4:18 PM
Preview Abstract
Abstract
Author:
Olivier Delaire
(Duke University and Oak Ridge National Laboratory)
Modern neutron and x-ray spectrometers can map phonon dispersions and
scattering rates throughout reciprocal space, providing unique insights into
microscopic scattering mechanisms, including anharmonicity, electron-phonon
coupling, or scattering by defects and nanostructures. In addition,
first-principles simulations enable the rationalization of extensive
experimental datasets. In particular, ab-initio molecular dynamics
simulations can capture striking effects of anharmonicity near lattice
instabilities. A number of high-performance thermoelectric materials are
found in the vicinity of lattice instabilities, including Pb chalcogenides
PbX, SnSe, Cu2Se, among others. The large phonon anharmonicity found in such
compounds suppresses the lattice thermal conductivity, enhancing their
thermoelectric efficiency. In this presentation, I will present results from
our investigations of phonons in these materials [1-4] using neutron and
x-ray scattering combined with first-principles simulations, focusing on
anharmonic effects near lattice instabilities. I will show how strong
anharmonicity can lead to emergent quasiparticles qualitatively different
from harmonic phonons, which we probe in our measurements and simulations of
the phonon self-energy. Commonalities between systems will be highlighted,
including connections between strong anharmonicity and the electronic
structure.
[1] O. Delaire, J. Ma, K. Marty, A. F. May, M. A. McGuire, M.-H. Du, D. J.
Singh, A. Podlesnyak, G. Ehlers, M. Lumsden, B. C. Sales, Nature Materials
10, 614 (2011).
[2] J. Ma*, O. Delaire*, A. F. May, C. E. Carlton, M. A. McGuire, L. H.
VanBebber, D. L. Abernathy, G. Ehlers, Tao Hong, A. Huq, Wei Tian, V. M.
Keppens, Y. Shao-Horn, and B. C. Sales, Nature Nanotechnology 8, 445 (2013).
[3] C.W. Li, O. Hellman, J. Ma, A.F. May, H.B. Cao, X. Chen, A.D.
Christianson, G. Ehlers, D.J. Singh, B.C. Sales, and O. Delaire, Physical
Review Letters (2014).
[4] C.W. Li,* J. Hong,* A.F. May, D. Bansal, S. Chi, T. Hong, G. Ehlers and
O. Delaire, Nature Physics 11, 1063 (2015).
[5] D. Bansal, J. Hong, C.W. Li, A.F. May, W. Porter, M.Y. Hu, D.L.
Abernathy, and O. Delaire, Phys. Rev. B 94, 054307 (2016)
*Funding from US DOE, Office of Basic Energy Sciences, Materials Science and Engineering Division, Office of Science Early Career program (DE-SC0016166), and as part of the S3TEC EFRC (DE-SC0001299).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.MAR.C34.7