Core-level binding-energy shifts at surfaces and in solids

TL;DR: In this paper, the core-level binding energies of the atoms in a monolayer, a multilayer and a single-crystal surface layer are explained in terms of the coordination number and the charge transfer at the Mg/Mo interfaces.

TL;DR: This work identified intermolecular coulombic decay relaxation processes following resonant X-ray excitation of the solute that highlight valence MnO4-(aq.)-H2O(l) electronic couplings and mapped the aqueous-phase electronic structure of this widely applied aQueous transition-metal complex ion.

TL;DR: The mechanisms responsible for the core-level binding-energy shifts that occur for surface and bulk atoms of the Al(100) surface are identified and characterized through theoretical analyses of the surface electronic structure and can be resolved by present-day high-resolution photoemission measurements.

TL;DR: In this paper, pulsed laser deposition nanometric layers of proton conducting calcium-doped lanthanum niobate (La 0.995 Ca 0.005 NbO 4 ) were deposited on nickel substrates in order to fabricate model structures of the electrolyte-anode interface present in potential proton-conducting solid oxide fuel cells (PC-SOFC).

TL;DR: In this article, the ground state of an interacting electron gas in an external potential was investigated and it was proved that there exists a universal functional of the density, called F[n(mathrm{r})], independent of the potential of the electron gas.

TL;DR: In this paper, the self-interaction correction (SIC) of any density functional for the ground-state energy is discussed. But the exact density functional is strictly selfinteraction-free (i.e., orbitals demonstrably do not selfinteract), but many approximations to it, including the local spin-density (LSD) approximation for exchange and correlation, are not.

TL;DR: In this paper, an analysis in quantitative form is given in terms of breakdowns of the electronic population into partial and total ''gross atomic populations'' and ''overlap populations'' for molecules.

TL;DR: Kind's new edition is to be welcomed as mentioned in this paper, with a revised format and attractive illustrations, and with the inclusion of much new material this book has become one of the best sources for undergraduate teaching, likely to give the student a wish to dig deeper into the solid state.