Electron paramagnetic resonance and electron spin echo study of supported and unsupported vanadium oxides
Date
1999
Authors
Luca, Vittorio
MacLachlan, Dugald
Bramley, Richard
Journal Title
Journal ISSN
Volume Title
Publisher
Royal Society of Chemistry
Abstract
Electron paramagnetic resonance (EPR) and electron spin echo envelope modulation (ESEEM) spectroscopies have been used to characterize paramagnetic centers in crystalline and gel forms of vanadium pentoxide as well as vanadia supported on silica, titania, and magnesia. A number of different paramagnetic centers are observed in the bulk and supported vanadia phases that are characterized by their spin Hamiltonian parameters. ESEEM data for all the bulk vanadium oxide samples show intense modulation at the51V Larmor frequency. This modulation originates from interlayer VO2+ species in gel samples and from V4+ centers in crystalline oxides. The intensity of the51V modulation varies considerably from sample to sample depending on the specific nature of the paramagnetic center. For the supported vanadia samples, complex EPR spectra are obtained that show two classes of signals. Signals with narrow linewidths and resolved hyperfine structure are observed suggesting magnetically isolated V4+ in addition to dipolar exchange broadened signals. ESEEM spectroscopy reveals that the spectra observed for vanadia supported on silica are from surface bound vanadyl species that interact with predominantly diamagnetic surface vanadia clusters. In contrast, for vanadia supported on titania, the V4+ signals observed by pulsed EPR show no modulation. The absence of modulation is attributed to well dispersed surface vanadyl species and subsurface V4+(6c) centers. Vanadium supported on magnesia interacts to form new magnesium vanadate phases containing V4+(6c). It is shown that ESEEM is a valuable tool for characterizing vanadia supported on various oxides.
Description
Keywords
Keywords: magnesium oxide; silicon dioxide; titanium dioxide; vanadium; vanadium pentoxide; article; catalyst; chemical structure; crystal; electron spin resonance; gel; structure analysis; surface property
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Source
Physical Chemistry Chemical Physics
Type
Journal article