This review paper concerns allylic oxidations and oxidative dehydrogenations. The corresponding catalysts often contain two or several oxide phases. The objective is to discuss the possible reasons why these phases cooperate (act synergetically). Different interpretations are reviewed. The authors discuss in detail the evidence showing that the synergy is often due to remote control. In such a mechanism, one phase, the donor, dissociates oxygen to form a surface mobile species which spills over to the other phase, or acceptor. The acceptor is the potentially active phase. This phase needs to be irrigated by spill-over oxygen to exhibit maximum activity and selectivity. The various modifications of the acceptor brought about by spill-over oxygen are discussed: maintaining the acceptor at a high oxidation state, preventing the destruction of the structure of the acceptor, and inhibiting the formation of carbonaceous deposits or coke precursors. Parallel experiments with the same two-phase catalysts catalysing an oxygen aided dehydration suggest that the role of spill-over oxygen is to protect some Bronsted acidity of the acceptor. This interpretation of the cooperation between phases permits definite roles to be attributed to the oxide phases present in multicomponent catalysts and to measure approximately their ability to act as donors or acceptors.

Phase Cooperation and Remote-control Effects in Selective Oxidation Catalysts

Antimony Oxides: A guide to phase changes during catalyst preparation

Phase cooperation between tin and antimony oxides in selective oxidation of isobutene to methacrolein. III: Coprecipitated catalysts

Efficient Deep Neural Networks for Classification of Alzheimer’s Disease and Mild Cognitive Impairment from Scalp EEG Recordings

The formation of electric circuits with carbon nanotubes and copper using tin solder

Optimization of VGG16 utilizing the Arithmetic Optimization Algorithm for early detection of Alzheimer's disease

Some reflections on mixed tin and antimony oxide catalysts

X-ray photoelectron spectroscopy and Auger electron spectroscopy analyses of an Sn-5at.%Sb mixed oxide catalyst showed that activation leads to an increase in concentration of antimony on its surface. This surface segregation is induced by the presence of oxygen in the gas phase. The active catalyst probably contains both antimony(V) and antimony(III) in addition to antimony(V) in solid solution with SnO 2 .

Characterization of Sn-5at.%Sb mixed oxide catalyst studied by x-ray photoelectron spectroscopy and Auger electron spectroscopy

Studies of the structural stability of Sn-Sb mixed oxide in the decomposition of isopropyl alcohol

Oxidative dehydrogenation of isopropyl alcohol on mixed tin and antimony oxide catalysts

S. Chokkalingam

Papers

Optimization of VGG16 utilizing the Arithmetic Optimization Algorithm for early detection of Alzheimer's disease

Some reflections on mixed tin and antimony oxide catalysts

Characterization of Sn-5at.%Sb mixed oxide catalyst studied by x-ray photoelectron spectroscopy and Auger electron spectroscopy

Studies of the structural stability of Sn-Sb mixed oxide in the decomposition of isopropyl alcohol

Oxidative dehydrogenation of isopropyl alcohol on mixed tin and antimony oxide catalysts