Showing total 3 results

1. First-principles identification of charge-transition levels of native defects in BaF2.

Author

Ibraheem, A. M., Eisa, M. H., Adlan, W., Amolo, George O., and Khalafalla, M. A. H.

Subjects

*BARIUM fluoride, *CRYSTAL defects, *DENSITY functional theory, *FERMI level, *BAND gaps

Abstract

This paper reports on semilocal and hybrid density functional analysis of charge-transition levels of native defects in BaF2 structure. The transition level is defined as the Fermi level where two defect charge states have the same formation energy. The errors arising from the small supercell size effects have been relieved through extrapolating the formation energies to the limit of infinite supercell size. The level placement in the corrected band gap is achieved using a correction factor obtained from the difference between the valence band maxima in semilocal and hybrid calculations. The band gap size from hybrid calculation is validated using the full-potential, linearized augmented planewave method with the modified Becke-Johnson exchange potential. Our results are sufficiently accurate and, thus, significant for direct comparison with experiments. [ABSTRACT FROM AUTHOR]

Published

2017

2. First-principles identification of charge-transition levels of native defects in BaF2.

Author

Ibraheem, A. M., Eisa, M. H., Adlan, W., Amolo, George O., and Khalafalla, M. A. H.

Subjects

BARIUM fluoride, CRYSTAL defects, DENSITY functional theory, FERMI level, BAND gaps

Abstract

This paper reports on semilocal and hybrid density functional analysis of charge-transition levels of native defects in BaF2 structure. The transition level is defined as the Fermi level where two defect charge states have the same formation energy. The errors arising from the small supercell size effects have been relieved through extrapolating the formation energies to the limit of infinite supercell size. The level placement in the corrected band gap is achieved using a correction factor obtained from the difference between the valence band maxima in semilocal and hybrid calculations. The band gap size from hybrid calculation is validated using the full-potential, linearized augmented planewave method with the modified Becke-Johnson exchange potential. Our results are sufficiently accurate and, thus, significant for direct comparison with experiments. [ABSTRACT FROM AUTHOR]

Published

2017

3. Recent advances in the study of core-valence luminescence (cross luminescence). Review.

Author

Khanin, Vasilii, Venevtsev, Ivan, and Rodnyi, Piotr

Subjects

*SCINTILLATORS, *CONDENSED matter physics, *LUMINESCENCE, *SYNCHROTRON radiation, *POSITRON emission tomography, *BAND gaps

Abstract

The short-wavelength sub-nanosecond luminescence in BaF 2 material, discovered in the early 80s, gave a new direction to research into fast scintillators and phosphors. In contrast to 'typical' luminescence occurring within the forbidden band gap, the new type of emission was due to transitions between the upper core and valence bands. Thus it was named core-valence luminescence (CVL); the terms cross-luminescence and Auger-free luminescence have also been used. Given its unusual nature, this new luminescence process has attracted considerable interest in the field of condensed matter physics. During the sequent decades (till the end of the previous century) CVL has been experimentally observed in several dozen compounds and the conditions for detecting CVL have been established. Interest in this kind of luminescence increased in recent years due to the emergence of new methods of crystal synthesis, the development of high-speed solid-state photodetectors, and the construction of unique modern set-ups using synchrotron radiation. This paper analyzes the numerous studies of CVL, obtained mainly over the past decade. Experimental and theoretical data on this topic are considered in detail. Special attention is given to new results on scintillation characteristics of BaF 2 in the form of single crystals, ceramics, nanoparticles, and composites. The features of CVL in binary and ternary compounds are discussed. Some Cs- and Ba-based ternary halides show relatively high light yields and represent promising fast scintillators. The prospects of using materials with CVL as fast scintillators for time-of-flight positron emission tomography and other applications are deliberated. • Overview of recent theoretical and experimental findings on Core Valence luminescence. • Most attractive CVL crystals for ultrafast scintillator applications analyzed. • Prospects for future studies and underexplored CVL materials listed. [ABSTRACT FROM AUTHOR]

Published

2023