Themed collection Recent Advances in Modelling Core-Electron Spectroscopy

This themed collection includes a series of articles on recent advances in theory, software, and analysis tools for modelling core-electron spectroscopy.

Time-dependent density functional theory provides a sufficiently accurate framework to study X-ray spectroscopies.

Green's function approaches facilitate efficient and accurate calculations of X-ray spectra that include key many-body effects.

An overview of the OCEAN code for calculating near-edge X-ray spectroscopy, including X-ray absorption and resonant inelastic X-ray scattering, using the Bethe-Salpeter equation approach.

The sensitivity of metal K-edge X-ray emission spectroscopy to ultrafast structural dynamics is explained by a multiconfigurational wavefunction model. This provides a new path to interpret spectra of non-equilibrium structures in photochemistry.

Electron–phonon interactions are fundamental to the behavior of chemical and physical systems.

Resonant and non-resonant Auger spectra of ozone are investigated with a multi-reference scheme based on the one-center approximation. The role of core-excited state dynamics and overlapping core-hole states are elucidated.

Gas phase structures of 2CzPN extracted from molecular dynamics are used to investigate the effects of disorder on the core and valence states using density functional theory, and compared to experimental X-ray photoelectron spectroscopy.

Extended X-ray absorption fine structure (EXAFS) has evolved into an unprecedented local-structure technique that is routinely used to study materials’ problems in the biological, chemical, and physical sciences.

A proper treatment of orbital relaxation and correlation, while addressing spin contamination and the shortcomings of the CVS, allows ΔCCSD to reach errors smaller than 0.5 eV compared to experimental X-ray absorption excitation energies.

An all-electron Bethe–Salpeter equation framework reveals the interplay of correlation and coherence in the resonant inelastic X-ray scattering in solids.

X-ray emission spectroscopy (XES) and resonant inelastic X-ray scattering (RIXS) are good target of extended quasiparticle theory which is applicable to any initial excited eigenstate. Application of GW with/without BSE is guaranteed by this theory.

A benchmark computational study of K-edge core-ionization energies of third-row elements using relativistic delta-coupled-cluster (ΔCC) methods and a revised core valence separation (CVS) scheme is reported.

A protocol for removing near-singularities in post-HF calculations of core-ionization energies and X-ray emission spectra is presented, enabling highly reliable calculations of such properties for large molecules and when using large basis sets.

In this article, we develop a relativistic exact-two-component nonorthogonal configuration interaction (X2C-NOCI) for computing L-edge X-ray spectra.

A deep neural network is developed to predict and understand the electronic and geometric characteristics of an X-ray absorption spectrum at the L_2/3-edge.

Tridimensional models of molecules, crystalline solids and liquids have been are obtained by Reverse Monte Carlo (RMC) using multiple-edge x-ray absorption spectroscopy and diffraction or MD. Full details on method and applications are presented.

We propose two color X-ray pump–probe spectroscopy, which opens new perspectives in studies of molecular rotational dynamics induces by the recoil effect in real-time. The feasibility of experimental observation is also discussed.

Renormalization schemes for improving the convergence of multiple scattering series expansions are studied. Numerical tests on a small Cu(111) cluster show that convergence rates can double or even that a divergent series can eventually converge.

Quantitative structural information of the single-atom catalyst was obtained by machine learning-assisted XANES data analysis.

Time-resolved X-ray absorption spectroscopy is a particularly sensitive probe of nonadiabatic molecular wave packet dynamics.