Positive active mass microstructure

This loop is, however, affected by the availability of the reactant oxygen, which in surplus destroys the precursor VPO. Further, oxygen is positively needed to activate and re-oxidize the VxOy sites but leads also to more water formation that in turn hydrothermally deactivates the active mass. Likewise, water is needed to separate, via hydrolysis, the vanadium phosphate into VxOy and mobile phosphate. The multiplicity of the feedback loops is at first puzzling but explains the apparent stable steady state that can be reached with a catalyst undergoing so many chemical and microstructural transformations the multiplicity of controls prevents one single factor becoming dominant and thus potentially destabilizing the whole process. 

Shown in Figure 8.3 is the opposing reactants geometry in which the two reactants enter the membrane from its opposite sides. A reaction plane is formed inside the catalytically active membrane. This implies that the flow front of either reactant is fairly uniform due to the well-engineered microstructure of inorganic membranes. The reactants arrive at the reaction plane in a stoichiometric ratio. Thus undesirable side reactions are reduced. It is noted that as any of the reactant flow rate or concentration changes, the reaction plane will migrate to a new position inside the membrane so that mass balance is maintained. 

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