Contact Us | Language: čeština English
Title: | Accurate X-ray absorption spectra near L- and M-edges from relativistic four-component damped response time-dependent density functional theory | ||||||||||
Author: | Konečný, Lukáš; Vícha, Jan; Komorovský, Stanislav; Ruud, Kenneth; Repiský, Michal | ||||||||||
Document type: | Peer-reviewed article (English) | ||||||||||
Source document: | Inorganic Chemistry. 2022, vol. 61, issue 2, p. 830-846 | ||||||||||
ISSN: | 0020-1669 (Sherpa/RoMEO, JCR) | ||||||||||
Journal Impact
This chart shows the development of journal-level impact metrics in time
|
|||||||||||
DOI: | https://doi.org/10.1021/acs.inorgchem.1c02412 | ||||||||||
Abstract: | The simulation of X-ray absorption spectra requires both scalar and spin-orbit (SO) relativistic effects to be taken into account, particularly near L- and M-edges where the SO splitting of core p and d orbitals dominates. Four-component Dirac-Coulomb Hamiltonian-based linear damped response time-dependent density functional theory (4c-DR-TDDFT) calculates spectra directly for a selected frequency region while including the relativistic effects variationally, making the method well suited for X-ray applications. In this work, we show that accurate X-ray absorption spectra near L-2,L-3- and M-4,M-5-edges of closed-shell transition metal and actinide compounds with different central atoms, ligands, and oxidation states can be obtained by means of 4c-DR-TDDFT. While the main absorption lines do not change noticeably with the basis set and geometry, the exchange-correlation functional has a strong influence with hybrid functionals performing the best. The energy shift compared to the experiment is shown to depend linearly on the amount of Hartee-Fock exchange with the optimal value being 60% for spectral regions above 1000 eV, providing relative errors below 0.2% and 2% for edge energies and SO splittings, respectively. Finally, the methodology calibrated in this work is used to reproduce the experimental L-2,L-3-edge X-ray absorption spectra of [RuCl2(DMSO)(2)(Im)(2)] and [WCl4(PMePh2)(2)], and resolve the broad bands into separated lines, allowing an interpretation based on ligand field theory and double point groups. These results support 4c-DR-TDDFT as a reliable method for calculating and analyzing X-ray absorption spectra of chemically interesting systems, advance the accuracy of state-of-the art relativistic DFT approaches, and provide a reference for benchmarking more approximate techniques. | ||||||||||
Full text: | https://pubs.acs.org/doi/10.1021/acs.inorgchem.1c02412 | ||||||||||
Show full item record |