Theory of dynamical structure factors in complex twisted materials

Lucas Lindsay; Rinkle Juneja; Simon Thebaud; Tribhuwan Pandey; Carlos A Polanco; Duncan H Moseley; Michael E Manley; Yongqiang Cheng; Barry Winn; Douglas L Abernathy; Raphael P Hermann

Theory of dynamical structure factors in complex twisted materials

ORAL

Abstract

Structural complexity underlies a variety of novel quasiparticle behaviors that can have profound impacts on material functionalities. Here we intimately examine the theory of lattice dynamical spectra of ‘twisted’ materials with combined rotational and translational symmetries. We advance a dynamical theory that incorporates the twist symmetry directly into the description of the phonon frequencies and eigenvectors, which naturally elucidates the underlying angular momenta of phonon bands. We apply this theory to build insights into dynamical structure factors and spectral observations from inelastic neutron and x-ray scattering experiments.

March 17, 2022, 10:48 AM – March 17, 2022, 11:00 AM

Publication: "Quasiparticle twist dynamics in non-symmorphic materials," R. Juneja, S. Thébaud, T. Pandey, C. A. Polanco, D. H. Moseley, M. E. Manley, Y. Q. Cheng, B. Winn, D. L. Abernathy, R. P. Hermann, L. Lindsay, Materials Today Physics 21, 100548 (2021).

Presenters

Lucas Lindsay

National Research Council

Authors

Lucas Lindsay

National Research Council
Rinkle Juneja

Oak Ridge National Lab
Simon Thebaud

Oak Ridge National Lab
Tribhuwan Pandey

Univ of Antwerp
Carlos A Polanco

Oak Ridge National Lab
Duncan H Moseley

Oak Ridge National Lab, Oak Ridge National Laboratory
Michael E Manley

Oak Ridge National Lab
Yongqiang Cheng

Oak Ridge National Laboratory, Oak Ridge National Lab
Barry Winn

Oak Ridge National Laboratory, Oak Ridge Nation Lab
Douglas L Abernathy

Oak Ridge National Lab
Raphael P Hermann

Oak Ridge National Lab