Partial oxidation of hydrogen sulfide to sulfur over vanadium oxides bronzes

Precise control of heat-treatment conditions to improve the catalytic performance of V2O5/TiO2 for H2S removal

The purpose of this study is to investigate the influences of atmospheric gas and temperature while preparing V₂O₅/TiO₂ catalysts to find a suitable heat-treatment method to improve catalytic performance during the process of H₂S removal. The catalysts prepared by wet-impregnation were heat-treated at different temperatures (400 or 600 ℃) under various atmospheres (Air, N₂, or H₂). The catalytic tests demonstrated that the catalyst heat-treated at 400 ℃ under N₂ atmosphere (N-400) possessed excellent catalytic activities regarding H₂S conversion (96.4%) and sulfur yield (89.1%). The characterization results revealed that the mild reducing condition employed for N-400 led to the formation of partially reduced V₂O₅ crystals and a strong V-Ti interaction owing to the anatase TiO₂ phase, resulting in the high oxygen vacancies on the catalyst surface. However, severe reducing conditions (H₂ or N₂ with 600 ℃) or the higher temperature (600 ℃) induced highly reduced V₂O_5-x or rutile TiO₂ related to a weak V-Ti interaction, respectively, which facilitated lower oxygen vacancies. This study is the first to demonstrate the significance of a precisely controlled heat-treatment to enhance catalytic performance for H₂S removal.

Direct cyanidation of silver sulfide by heterolytic C–CN bond cleavage of acetonitrile

Extraction of silver as silver cyanide from silver sulfide was made possible using acetonitrile as the source of cyanide. The process of cyanidation took place through the oxidation of sulfide to sulfur oxides and cleavage of the C–CN bond of acetonitrile. The reaction was found to be catalyzed by vanadium pentoxide and hydrogen peroxide. The different species involved in the cyanidation process were duly characterized using FTIR, ESI-MS, HRMS, XPS and UV-vis spectroscopic analysis. The mechanism of the cyanidation process was confirmed through in situ FTIR analysis.

Herein, we report the cleavage of the C–CN bond of acetonitrile, catalyzed by vanadium pentoxide, for the direct cyanidation of silver sulfide.

V-Containing Mixed Oxide Catalysts for Reduction–Oxidation-Based Reactions with Environmental Applications: A Short Review

V-containing mixed oxide catalytic materials are well known as active for partial oxidation reactions. Oxidation reactions are used in industrial chemistry and for the abatement of pollutants. An analysis of the literature in this field during the past few years shows a clear increase in the use of vanadium-based materials as catalysts for environmental applications. The present contribution makes a brief revision of the main applications of vanadium containing mixed oxides in environmental catalysis, analyzing the properties that present the catalysts with a better behavior that, in most cases, is related with the stabilization of reduced vanadium species (as V4+/V3+) during reaction.

Synthesis and Characterization of Ag-Modified V2O5Photocatalytic Materials

V2O5powders modified with different theoretical silver contents (1, 5, 10, 15, and 20 wt% as Ag2O) were obtained with acicular morphologies observed by scanning electron microscopy (SEM). Shcherbinaite crystalline phase is transformed into the Ag0.33V2O5crystalline one with the incorporation and increase in silver content as was suggested by X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS) analysis. With further increase in silver contents the Ag2O phase appears. Catalysts were active in photocatalytic degradation of malachite green dye under simulated solar light, which is one of the most remarkable facts of this work. It was found that V2O5-20Ag was the most active catalytic formulation and its activity was attributed to the mixture of coupled semiconductors that promotes the slight decrease in the rate of the electron-hole pair recombination.