Hydrogen ions acidic destruction

The acidic destruction of montmorillonite results in the release of silicon and aluminum. The initial fast exchange of surface cations by hydrogen ions is followed by the release of aluminum and silicon. The dissolution rate of Si is higher than that of A1 and is influenced by the relative ratios of basal siloxane and edge surfaces. The shift of pH to more basic values by the ion-exchange processes and the hydrolysis of dissolved species induce the formation of secondary amorphous solids, initiating the formation of amorphous aluminosilicates (Sondi et al. 2008). 

The behaviour of the hydrogen ion represents a fundamental chemical principle and is critical to the toxicity profile of many ionizable substances. Corrosivity is a dramatic, destructive and obvious result of very acidic or very... 

Destruction of the masking ligand by chemical reaction may be possible, as in the oxidation of EDTA in acid solutions by permanganate or another strong oxidizing agent. Hydrogen peroxide and Cu(II) ion destroy the tartrate complex of aluminum. 

Schistosoma japonicum. The carbobenzoxy (CBz) protected template 160 was initially converted to the a, p-dehydrolactone 161 via the phosphate ester, before undergoing cycloaddition to ylide 162, generated in situ by acidic treatment of A(-benzyl-A(-(methoxymethyl)trimethylsilyl amine. The resultant cycloadduct (163) was isolated in 94% yield as a single diastereoisomer. Destructive template removal, by catalytic hydrogenation, released (5)-( )-cucurbitine, after ion-exchange chromatography, as the free amino acid in 90% yield (Scheme 3.46). 

Hydrogen cyanide formation may contribute to the toxicity of snake venom, owing to the high levels of L-amino acid oxidase in some snake venoms. This enzyme is harmless on injection, but the tissue destruction caused by other venom components probably provides the required substrate and cofactor for HCN production. Cyanide inhibits ion... 

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