First-Principles Demonstration of Nonadiabatic Thouless Pumping of Electrons in a Molecular System
ORAL
Abstract
We demonstrate nonadiabatic Thouless pumping of electrons in trans-polyacetylene in the framework of Floquet engineering using first-principles theory. We identify the regimes in which the quantized pump is operative with respect to the driving electric field for a time-dependent Hamiltonian. By employing the time-dependent maximally localized Wannier functions in real-time time-dependent density functional theory simulation, we connect the winding number, a topological invariant, to a molecular-level understanding of the quantized pumping. Using a gauge-invariant formulation called dynamical transition orbitals, an alternative viewpoint on the nonequilibrium dynamics is obtained in terms of the particle-hole excitation. A single time-dependent transition orbital is found to be largely responsible for the observed quantized pumping. Further, robustness of the nonadiabatic Thouless pumping is examined by introducing different types of chemical modifications.
*This work was supported by the National Science Foundation under Award Nos. CHE-1954894 and OAC-17402204. D.C.Y. was supported by an appointment to the Intelligence Community Postdoctoral Research Fellowship Program at Massachusetts Institute of Technology, administered by Oak Ridge Institute for Science and Education through an interagency agreement between the U.S. Department of Energy and the Office of the Director of National Intelligence.
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Publication:1. Zhou, R., Yost, D. C., & Kanai, Y. (2021). First-Principles Demonstration of Nonadiabatic Thouless Pumping of Electrons in a Molecular System. The Journal of Physical Chemistry Letters, 12(19), 4496-4503. 2. Zhou, R., & Kanai, Y. (2021). Dynamical transition orbitals: A particle–hole description in real-time TDDFT dynamics. The Journal of Chemical Physics, 154(5), 054107.
