Abstract
Optical and magnetic properties of SiO2:C nanopowders obtained by chemical and thermal modification of fumed silica were studied by Fourier transform infrared spectroscopy, Raman, continuous wave (CW) electron paramagnetic resonance (EPR), echo-detected EPR and pulsed electron nuclear double resonance (ENDOR) spectroscopy. Two overlapping signals of Lorentzian lineshape were detected in CW EPR spectra of the initial SiO2:C. The EPR signal at g = 2.0055(3) is due to the silicon dangling bonds, which vanishes after thermal annealing, and the second EPR signal at g = 2.0033(3) was attributed to the carbon-related defect (CRD). The annealing of the SiO2:C samples gives rise to the increase of the CRD spin density and shift to the higher g-values due to the appearance of the oxygen in the vicinity of the CRD. Based on the temperature-dependent behavior of the CRD EPR signal intensity, linewidth and resonance field position we have attributed it to the spin system with non-localized electrons hopping between neighboring carbon dangling bonds, which undergo a strong exchange interaction with a localized spin system of carbon nanodots. The observed motional narrowing of the CRD EPR signal in the temperature interval from 4 to 20 K indicates that electrons are mobile at 4 K which can be explained by a quantum character of the conductivity in the vicinity of the carbon layer. The electrons trapped in quantum wells move from one carbon nanodot to another by hopping process through the energy barrier. The fact that echo-detected EPR signal at g = 2.0035(3) was observed in SiO2:C sample annealed at Tann ≥ 700 °C serves as evidence that non-localized electrons coexist with localized electrons that have the superhyperfine interaction with surrounding 13C and 29Si nuclei located at the SiO2:C interface. The presence of the superhyperfine interaction of CRD with 1H nuclei indicates the existence of hydrogenated regions in SiO2:C sample.
Highlights
Silica-carbon SiO2:C composites owing to their high electrical conductivity, high thermal stability and high resistance to organic solvents are widely used in industry as adsorbents for medicinal, analytical and extraction purposes
Optical and magnetic properties of the initial and annealed in the temperature range of 500–800 °C carbonized silica (SiO2:C) nanopowders were studied by Fourier transform infrared spectroscopy (FTIR), Raman, continuous wave (CW) electron paramagnetic resonance (EPR), and pulsed EPR methods, including echo-detected EPR (ED EPR) and pulsed electron nuclear double resonance (ENDOR) spectroscopy, in the temperature interval from 4.2 to 292 K
The effect of the thermal annealing on the EPR spectra of the SiO2:C nanopowders was studied in the temperature range of Tann = 500–800 °C
Summary
Silica-carbon SiO2:C composites (carbosils) owing to their high electrical conductivity, high thermal stability and high resistance to organic solvents are widely used in industry as adsorbents for medicinal, analytical and extraction purposes. The nature of the broadband photoluminescence (PL) of carbon incorporated nanostructured silica remains unclear. It was recently demonstrated that carbon nanodots, including the graphene nanodots and graphene oxide nanodots, exhibit a broadband PL in the near ultraviolet and visible spectral ranges [2,3,4,5]. The red spectral shift of the PL observed in annealed SiO2:C nanopowders and porous SiO2:C layers was attributed to an increase of the size of carbon clusters [6]. The analysis of the carbon phases and carbon local electronic structure is of great importance to improve the properties of the SiO2:C materials and to find out the relation between PL and carbon phase incorporated in the SiO2 nanostructured matrix
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