INVESTIGADORES
CADUS Luis Eduardo
artículos
Título:
MOLIBDENUM ROLE: Mo-Sm-V-O CATALYTIC SYSTEM FOR PROPANE OXIDATIVE DEHYDROGENATION OF PROPANE
Autor/es:
BARBERO, B; LUIS EDUARDO CADUS
Revista:
APPLIED CATALYSIS A-GENERAL
Editorial:
ELSEVIER SCIENCE BV
Referencias:
Año: 2003 vol. 252 p. 133 - 147
ISSN:
0926-860X
Resumen:
SmVO4-impregnated molybdenum oxide catalysts have been prepared with different molybdenum amounts to obtain
surface coverages below and above the theoretical monolayer. The physicochemical properties of the catalysts were characterized
by BET specific surface area measurements, X-ray diffraction (XRD), temperature-programmed reduction (TPR),
Raman spectroscopy, and X-ray photoelectron spectroscopy (XPS). At low molybdenum loading (surface coverage below
the theoretical monolayer), surface molybdenum oxide species were detected by Raman. TPR and XPS techniques were
used to investigate the reducibility of this species. The results suggest that a strong molybdenumSmVO4 interaction exist.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
surface coverages below and above the theoretical monolayer. The physicochemical properties of the catalysts were characterized
by BET specific surface area measurements, X-ray diffraction (XRD), temperature-programmed reduction (TPR),
Raman spectroscopy, and X-ray photoelectron spectroscopy (XPS). At low molybdenum loading (surface coverage below
the theoretical monolayer), surface molybdenum oxide species were detected by Raman. TPR and XPS techniques were
used to investigate the reducibility of this species. The results suggest that a strong molybdenumSmVO4 interaction exist.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
surface coverages below and above the theoretical monolayer. The physicochemical properties of the catalysts were characterized
by BET specific surface area measurements, X-ray diffraction (XRD), temperature-programmed reduction (TPR),
Raman spectroscopy, and X-ray photoelectron spectroscopy (XPS). At low molybdenum loading (surface coverage below
the theoretical monolayer), surface molybdenum oxide species were detected by Raman. TPR and XPS techniques were
used to investigate the reducibility of this species. The results suggest that a strong molybdenumSmVO4 interaction exist.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
4-impregnated molybdenum oxide catalysts have been prepared with different molybdenum amounts to obtain
surface coverages below and above the theoretical monolayer. The physicochemical properties of the catalysts were characterized
by BET specific surface area measurements, X-ray diffraction (XRD), temperature-programmed reduction (TPR),
Raman spectroscopy, and X-ray photoelectron spectroscopy (XPS). At low molybdenum loading (surface coverage below
the theoretical monolayer), surface molybdenum oxide species were detected by Raman. TPR and XPS techniques were
used to investigate the reducibility of this species. The results suggest that a strong molybdenumSmVO4 interaction exist.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
At higher molybdenum loadings (exceeding the monolayer coverage), crystalline MoO3 is formed. The catalytic behavior
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
was evaluated in the propane oxidative dehydrogenation (ODH). The incorporation of low molybdenum loading results in
an increase of the selectivity to propene. The highest yield to propene was obtained on SmVO4-impregnated with 3mol%
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4-impregnated molybdenum oxide catalysts was compared with that of SmVO4-impregnated
vanadium oxide catalysts.
vanadium oxide catalysts.
vanadium oxide catalysts.
Mo. The performance of SmVO4
