1985
DOI: 10.2166/wst.1985.0129
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Kinetic Studies of the Microbiological Conversion of Sulphate to Hydrogen Sulphide and their Relevance to Sulphide Generation within Sewers

Abstract: The relevance of the studies carried out, to the important practical problem of predicting sulphide generation rates within sewers, is discussed in the introduction section of the paper. The predictive equations presently in use are compared, and the desirability of replacing these empirical equations by a more scientific approach based on an analysis of mass transport and biochemical reaction is stressed. A theoretical analysis of mass transport and metabolism of sulphate during laminar flow in… Show more

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Cited by 15 publications
(6 citation statements)
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“…Some empirical models to explain the sulfide build-up in sewer systems have been published (3,24,31), but the biofilm kinetics are not directly taken into account. Studies with a tubular biofilm reactor have resulted in sulfide production rates comparable to those found in actual sewer systems (9).…”
mentioning
confidence: 76%
“…Some empirical models to explain the sulfide build-up in sewer systems have been published (3,24,31), but the biofilm kinetics are not directly taken into account. Studies with a tubular biofilm reactor have resulted in sulfide production rates comparable to those found in actual sewer systems (9).…”
mentioning
confidence: 76%
“…The reduction of sulfate as a respiratory type of metabolism is associated with electron transport phosphorylation. Holder et al 44 conducted kinetic studies with flowing simulated sewage through tubes containing biofilms of mixed cultures of SRB. They determined that the zeroorder sulfate removal rate was 30 mg/h/cm 3 (based on a slime depth of 45 Jim) at the optimum temperature of 41°C; it was 5 to 8 mg/h/cm 3 (based on a slime depth of 25 (im) at 20°C.…”
Section: Carbon Sourcementioning
confidence: 99%
“…Sulfate reduction in biofilms has therefore been quantified from * Corresponding author. mass balance calculations in anaerobic bioreactor systems (32,33,64) or by tracer techniques in biofilms growing on metal surfaces incubated under anaerobic conditions (55).…”
mentioning
confidence: 99%