Time-Dependent Multiconfiguration Self-Consistent-Field Study on Resonantly Enhanced High-Harmonic Generation from Transition Metal Elements
Abstract
We theoretically study high-harmonic generation (HHG) from transition metal elements Mn and Mn, using full-dimensional, all-electron, first-principles simulations. The HHG spectra calculated with the time-dependent complete-active-space self-consistent-field (TD-CASSCF) and occupation-restricted multiple-active-space (TD-ORMAS) methods exhibit a prominent peak at eV, successfully reproducing resonant enhancement observed in previous experiments [R.A. Ganeev \textit{et al.}, Opt. Express \textbf{20}, 25239 (2012)]. Artificially freezing orbitals in simulations results in its disappearance, which shows the essential role played by electrons in the resonant harmonics (RH). Further transition-resolved analysis unambiguously identifies constructively interfering - () giant resonance transitions as the origin of the RH, as also implied by its position in the spectra. Time-frequency analysis indicates that the recolliding electron combines with the parent ion to form the upper state of the transitions. In addition, this study shows that the TD-CASSCF and TD-ORMAS methods can be applied to open-shell atoms with many unpaired inner electrons.
Cite
@article{arxiv.1903.07857,
title = {Time-Dependent Multiconfiguration Self-Consistent-Field Study on Resonantly Enhanced High-Harmonic Generation from Transition Metal Elements},
author = {Imam S. Wahyutama and Takeshi Sato and Kenichi L. Ishikawa},
journal= {arXiv preprint arXiv:1903.07857},
year = {2019}
}
Comments
7 pages, 8 figures