Obtaining Stationary States in Density Functional Theory Using Imaginary Time Propagation

ORAL

Abstract

Density functional theory (DFT) is widely successful for determining electronic and structural properties of materials and molecules. In order to perform a DFT calculation, the Kohn-Sham nonlinear equations must be solved self-consistently, a task usually achieved using self-consistent field (SCF) loops. However, for large systems SCF can occasionally struggle to find the ground state. Using time-dependent DFT in imaginary time, a given starting state can be purified into its lowest-energy component with reliable monotonic convergence. With appropriate constraints, it is also possible to obtain excited states with imaginary time propagation (ITP). We compare and analyze the performance of ITP and SCF in a few difficult systems, and present a few excited state calculations performed with the method.

*This work was supported by the Army Research Office MURI Award No. W911NF-14-0247. We used computational resources on Odyssey cluster at Harvard University and XSEDE (NSF Grant No. ACI-1053575).

Presenters

  • Cedric Flamant

    • Harvard University

Authors

  • Cedric Flamant

    • Harvard University

  • Grigory Kolesov

    • Harvard University

  • Efstratios Manousakis

    • University of Athens, Panepistimioupolis, Zografos, Athens, Greece; Florida State University, Tallahassee, FL, USA; National High Magnetic Field Laboratory
    • Department of Physics and National High Magnetic Field Laboratory, Florida State University
    • Florida State University
    • National High Magnetic Field Laboratory, Florida State University
    • Physics, Florida State University and National High Magnetic Field Laboratory
    • Florida State Univ

  • Efthimios Kaxiras

    • Harvard University
    • Department of Physics, Harvard University
    • Physics, Harvard University