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First-Principles Study of Optical Absorption Energies, Ligand Field and Spin-Hamiltonian Parameters of Cr<sup>3+</sup> Ions in Emeralds

Mihail Atanasov, Emiliana-Laura Andreici Eftimie, N.M. Avram, M.G. Brik, Frank Neese

2021Inorganic Chemistry23 citationsDOI

Abstract

Herein, we study the electronic structure, energies, and vibronic structure of optical d-d transitions of Cr3+ ions doped in beryl (Be3Si6Al2O18:Cr3+, emerald). A computational protocol is developed that combines periodic density functional theory (for modeling of the bulk crystalline lattice of emerald) and the multireference configuration interaction complete active space self-consistent field method supplemented with n-electron valence second-order perturbation theory (for the calculation of the energy levels, wave functions, and spin-Hamiltonian and ligand-field parameters of the trigonal Cr3+ centers in the [CrO6]9– clusters embedded in an extended point charge field). Ligand-field parameters were extracted from mapping the effective ligand-field Hamiltonian onto the full many-particle Hamiltonian from one side and from a direct fit to energies of computed d-d transitions on the other side. These have been analyzed using ab initio ligand-field theory. The quality of the theoretical predictions is critically assessed through a detailed comparison with the available experimental data.

Topics & Concepts

ChemistryLigand field theoryHamiltonian (control theory)Ab initioIonComplete active spaceValence (chemistry)Ab initio quantum chemistry methodsDensity functional theoryAtomic physicsComputational chemistryMolecular physicsPhysicsMoleculeBasis setMathematical optimizationMathematicsOrganic chemistryMineralogy and Gemology StudiesCrystal Structures and PropertiesGlass properties and applications