100 MeV silver ions induced defects and modifications in silica glass

Abstract

A few silica glass samples having 1cm2 area and 0.1cm thickness were irradiated with 100MeV energy Ag7+ ions for the fluences ranging from 1×1012ions/cm2 to 5×1013ions/cm2. The optical properties and the corresponding induced defects were characterised by the techniques such as UV–Visible, Photoluminescence (PL), Fourier transform infrared (FTIR), and Electron spin resonance (ESR) spectroscopy. The UV–Visible absorption spectra show two peaks, one at 5eV and another weak peak at 5.8eV. A peak observed at 5.0eV corresponds to B2 band (oxygen deficiency in SiO2 network) and the peak at 5.8eV is due to the paramagnetic defects like E′ centre. The intensities of these peaks found to be increased with increase in ion fluence. It attributes to the increase in the concentration of E′ centres and B2 band respectively. In addition, the optical band gap energy, Urbach energy and the defects concentration have been calculated using Urbach plot. The optical band gap found to be decreased from 4.65eV to 4.39eV and the Urbach energy found to be increased from 60meV to 162meV. The defect concentration of nonbridging oxygen hole centres (NBOHC) and E′ centres are found to be increased to 1.69×1013cm−3 and 3.134×1014cm−3 respectively. In PL spectra, the peak appeared at 1.92eV and 2.7eV envisage the defects of nonbridging oxygen hole centres and B2α oxygen deficient centres respectively. ESR spectra also confirms the existence of E′ and NBOHC centres. FTIR spectra shows scissioning of SiOSi bonds and the formation of SiH and SiOH bonds, which supports to the co-existence of the defects induced by Ag7+ irradiation.