Coupling catalytic hydrolysis and oxidation for CS sub(2) removal

Coupling catalytic hydrolysis and oxidation for CS sub(2) removal

CS sub(2) removal was obtained by coupling catalytic hyidation on bi-functional catalyst. On the hydrolysis active sites, CS sub(2) is hydrolyzed to H sub(2)S, while on the oxidation active sites, H sub(2)S is oxidized to elemental S or sulfuric acid deposited on the porous support. The above proces...

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Veröffentlicht in:Journal of environmental sciences (China) 2008-01, Vol.20 (4), p.436-440
Hauptverfasser: Wang, Li, Wu, Diyong, Wang, Shudong, Yuan, Quan
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creator Wang, Li
Wu, Diyong
Wang, Shudong
Yuan, Quan
description CS sub(2) removal was obtained by coupling catalytic hyidation on bi-functional catalyst. On the hydrolysis active sites, CS sub(2) is hydrolyzed to H sub(2)S, while on the oxidation active sites, H sub(2)S is oxidized to elemental S or sulfuric acid deposited on the porous support. The above process can be expressed as follows: [MathML equation] H sub(2)S oxidation eliminates its prohibition on CS sub(2) hydrolysis so that the rate of coupling removal CS sub(2) is 5 times higher than that of CS sub(2) hydrolysis. The same active energy of hydrolysis and coupling reaction also indicates that H sub(2)S oxidation does not change the reaction mechanism of CS sub(2) hydrolysis. Temperature has obvious effect on the process while the mole ratio of O sub(2) concentration to CS sub(2) concentration (O/S) does not, especially in excess of 2.5. The formation of sulfuric acid on the catalyst surface poisons hydrolysis active sites and causes the decrease of left OH super(-1) concentration on the catalysts surface. Lower temperature is suggested for this bi-functional catalyst owing to the low yield ratio of S/SO sub(4) super(2-).
doi_str_mv 10.1016/S1001-0742(08)62076-8
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On the hydrolysis active sites, CS sub(2) is hydrolyzed to H sub(2)S, while on the oxidation active sites, H sub(2)S is oxidized to elemental S or sulfuric acid deposited on the porous support. The above process can be expressed as follows: [MathML equation] H sub(2)S oxidation eliminates its prohibition on CS sub(2) hydrolysis so that the rate of coupling removal CS sub(2) is 5 times higher than that of CS sub(2) hydrolysis. The same active energy of hydrolysis and coupling reaction also indicates that H sub(2)S oxidation does not change the reaction mechanism of CS sub(2) hydrolysis. Temperature has obvious effect on the process while the mole ratio of O sub(2) concentration to CS sub(2) concentration (O/S) does not, especially in excess of 2.5. The formation of sulfuric acid on the catalyst surface poisons hydrolysis active sites and causes the decrease of left OH super(-1) concentration on the catalysts surface. 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title Coupling catalytic hydrolysis and oxidation for CS sub(2) removal
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