Abstract
The vibrational infrared (IR) and Raman spectra of seven substitutional defects in bulk silicon are computed, by
using the quantum mechanical CRYSTAL code, the supercell scheme, an all electron Gaussian type basis
set and the B3LYP functional. The relative stability of various spin states has been evaluated, the geometry
optimized, the electronic structure analyzed. The IR and Raman intensities have been evaluated analitically.
In all cases the IR spectrum is dominated by a single N peak (or by two or three peaks with very close
wavenumbers), whose intensity is at least 20 times larger than the one of any other peak. These peaks fall
in the 645–712 cm1 interval, and a shift of few cm1 is observed from case to case. The Raman spectrum
of all defects is dominated by an extremely intense peak at about 530 cm1
, resulting from the (weak) perturbation of the peak of pristine silicon.
Lingua originale | Inglese |
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pagine (da-a) | 20939-20950 |
Numero di pagine | 12 |
Rivista | Physical Chemistry Chemical Physics |
Volume | 21 |
Numero di pubblicazione | 37 |
DOI | |
Stato di pubblicazione | Pubblicato - 2019 |