Electronic and optical properties of thiogermanate AgGaGeS: theory and experiment.

The electronic and optical properties of an AgGaGeS crystal were studied by first-principles calculations, where the full-potential augmented plane-wave plus local orbital (APW+lo) method was used together with exchange-correlation pseudopotential described by PBE, PBE+, and TB-mBJ+ approaches. To verify the correctness of the present theoretical calculations, we have measured for the AgGaGeS crystal the XPS valence-band spectrum and the X-ray emission bands representing the energy distribution of the electronic states with the biggest contributions in the valence-band region and compared them on a general energy scale with the theoretical results. Such a comparison indicates that, the calculations within the TB-mBJ+ approach reproduce the electron-band structure peculiarities (density of states - DOS) of the AgGaGeS crystal which are in fairly good agreement with the experimental data based on measurements of XPS and appropriate X-ray emission spectra.

Optical and electronic properties of lithium thiogallate (LiGaS): experiment and theory.

We report the relation between the optical properties and electronic structure of lithium thiogallate (LiGaS) by performing XPS and XES measurements and theoretical calculations. According to the XPS measurements, the LiGaS crystals grown by the Bridgman-Stockbarger method possess promising optical qualities, low hygroscopicity and high stability upon middle-energy Ar-ion irradiation. The difference in the LiGaS band gaps obtained by theoretical calculations and experimental measurements was, for the first time, reduced down to 0.

Theoretical and experimental study on the electronic and optical properties of KRbPbBr: a promising laser host material.

The data on the electronic structure and optical properties of bromide KRbPbBr achieved by first-principle calculations and verified by X-ray spectroscopy measurements are reported. The kinetic energy, the Coulomb potential induced by the exchange hole, spin-orbital effects, and Coulomb repulsion were taken into account by applying the Tran and Blaha modified Becke-Johnson function (TB-mBJ), Hubbard U parameter, and spin-orbital coupling effect (SOC) in the TB-mBJ + U + SOC technique. The band gap was for the first time defined to be 3.

Manifestation of Anomalous Weak Space-Charge-Density Acentricity for a TlHgBr Single Crystal.

Density functional theory (DFT) calculations within the concept of the MBJ+U+SO (modified Becke-Johnson potential + U + spin orbit) approach were performed for a TlHgBr single crystal for the first time assuming weak noncentrosymmetry (space group P4nc). Excellent agreement was achieved between the calculated and experimental band-gap-energy magnitudes as well as the density of electronic states measured by the X-ray photoelectron spectroscopy method. It is a very principal result because usually the DFT calculations underestimate the energy-gap values.

The use of the FEFF8 code to calculate the XANES and electron density of states of some sulfides.

The FEFF8 was used to calculate x-ray absorption spectra (XANES) and the local partial electron density of states (LDOS) for several sulfides: InPS4 (twice defective chalcopyrite), CdIn2S4 (normal spinel) and Tl3AsS3 (space group R3m). The calculated XANES are compared with experimental spectra. The self-consistent MT-potentials found for clusters of about 35 atoms were used to calculate XANES and LDOS for clusters of 87 atoms in the approach of full multiple scattering.