Cu/ZrO2 catalysts obtained by impregnation of ZrO2 and
complexation with citric acid were studied for CO2 hydrogenation
to methanol. The catalyst structure, texture,
and active copper surface were determined using XRD, BET, and reactive
adsorption of N2O, respectively. The XPS and Auger spectroscopies
were used to determine the surface structure and copper electronic
state. FT-IR pyridine adsorption was studied to determine acidity
of the catalysts. The results of quantum-chemical calculations concerning
the formation of oxygen vacancies in monoclinic and tetragonal ZrO2 have been also presented. It was found that selection of
the appropriate conditions of the catalyst preparation influences
the degree of copper dispersion, its electronic state, and contents
of the zirconia polymorphic phases (tetragonal and monoclinic). The
presence of oxygen vacancies stabilizes both the thermodynamically
unstable t-ZrO2 phase and Cu1+ cations, which
are present in the vicinity of oxygen vacancies. Complexes formed
preferentially on tetragonal ZrO2 built from Cu cations
and oxygen vacancies are the acid centers active in methanol synthesis
reaction; therefore the catalytic activity toward methanol increases
with increasing t-ZrO2 content. The implications of the
obtained results for the mechanism of the catalytic hydrogenation
of CO2 are discussed.
Photocatalytic activity of Ag/TiO(2) composites obtained by photoreduction treatment (PRT) was investigated. The composite materials, containing various ratio of silver nanoparticles (0.6-3.7 wt %) were obtained by depositing silver on the Evonic-Degussa P25 titania surface. Selected samples whose color varied between light rose and purple brown were examined by SEM, TEM, XPS, DRS, and BET techniques. Flat band potential was determined using Roy method. TEM analysis showed spherically shaped silver nanoparticles of the diameter 4-12 nm. The XPS measurements revealed that silver particles were obtained mainly in metallic form. DRS spectra and photovoltage measurements showed that silver nanoparticles modified the P25 spectral properties but they changed neither the band gap nor the location of flat band potential. The photocatalytic activity of Ag/P25 composite was compared to the photocatalytic activity of pure P25 in the photooxidation reaction of an important potable water contaminant humic acid (HA) and two model compounds, oxalic acid (OxA) and formic acid (FA). The photodecomposition reaction was investigated in a batch reactor containing aqueous suspension of a photocatalyst illuminated by either UV or artificial sunlight (halogen lamp). The tests proved that a small amount of silver nanoparticles deposited on the titania surface triggers the increase in photocatalytic activity; this increase depends, however, on the decomposed substance.
Ag/ZrO 2 and Ag/ZrO 2 /ZnO catalysts obtained by the coprecipitation method were studied in the CO 2 hydrogenation to methanol. The catalyst structure was determined using X-ray diffraction (XRD) and Thermo-Programmed Reduction (TPR). The X-ray Photoelectron Spectroscopy (XPS) and Auger spectroscopies were used to determine the silver electronic state. It was found that selection of the appropriate conditions of the catalyst preparation influences silver dispersion degree, its electronic state, and contents of the zirconia polymorphic phases (tetragonal and monoclinic). The presence of oxygen vacancies stabilizes both the thermodynamically unstable t-ZrO 2 phase and the Ag þ cations, which are present in the vicinity of oxygen vacancies. The catalytic activity to methanol increases with increasing t-ZrO 2 content but RWGS reaction is accelerated by dispersed metallic silver. The implications of the obtained results for the mechanism of the catalytic hydrogenation of CO 2 are discussed.
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