2.5 eV Pulsed Cathodoluminesce band of silicon dioxide

Abstract

Room-temperature (RT) Pulsed Cathodoluminescence (PCL) spectra of a set of pure synthetic (both crystalline and amorphous) silicon dioxide materials were studied. It is shown, that the PCL spectra of all samples (both amorphous and crystalline) possess a separate band at 495 nm (2.5 eV). This band is the most intensive one in PCL spectra of disordered materials. The RT PCL band at 495 nm (2.5 eV) of α-quartz single crystal is polarized in XY crystalline plane (perpendicular to the 3rd order symmetry axis). The structure of this band was detected. It consists of three peaks: at 4802 nm (2.580.01 eV), 487 nm (2.550.01 eV) and 4932 nm (2.520.01 eV). Energy separation between peaks is equal in order of magnitude to energies of LixOy molecular vibrations and to the energy of optical phonon in α-quartz. It is shown, that the emission band at 495 nm (2.5 eV) in RT PCL spectra of α-quartz single crystal is related to the bulk emission centers, not to the surface-related ones. The annealing behaviors of the 495 nm (2.5 eV) bands in spectrum of amorphous and crystalline SiO2 are close to each other. This fact may be the manifestation of identical origin of these bands. The following explanation of experimental data is proposed: the origin of 495 nm (2.5 eV) band in pure silicon dioxide is related to the recombination of non-bridging oxygen NBO--Li+ centers.