Nitrite effectively inhibits sulfide and methane production in a laboratory scale sewer reactor

• Published in: Water research (Oxford) Vol. 42; no. 14; pp. 3961 - 3971
• Main Authors: Mohanakrishnan, J., Gutierrez, O., Meyer, R.L., Yuan, Z.
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.08.2008; Elsevier Science
• Subjects: Applied sciences; Bacteria - drug effects; Bacteria - metabolism; Biofilm; Biofilms - drug effects; Bioreactors; Exact sciences and technology; Hydrogen Sulfide - chemistry; Methane; Methane - chemistry; Methane - metabolism; Nitrite; Nitrites - chemistry; Nitrites - pharmacology; Other industrial wastes. Sewage sludge; Pollution; Sewage; Sewer; Sulfate; Sulfide; Wastes; Water treatment and pollution; Sulfide; Methane; Biofilm; Sewer; Sulfate; Nitrite; Nitrites; Nitrates; Sulfates; Pollutant emission; Optimization; Anaerobe; Greenhouse gas; Air pollution; Oxidation; Sewer network; Nitrogen protoxide; Reactor
• ISSN: 0043-1354; 1879-2448
• DOI: 10.1016/j.watres.2008.07.001

The production and emission of hydrogen sulfide and methane by anaerobic microoganisms in sewer systems is a well-documented problem. The effectiveness of nitrite in controlling sulfide and methane production was tested in a laboratory scale sewer reactor. Nitrite was continuously dosed in the reactor for 25 days at concentrations of 20–140 mg N/L. No sulfide and methane accumulation was observed in the reactor in the presence of nitrite. A significant reduction was observed in the sulfate reduction and methane production capabilities of the biofilm. Nitrite also stimulated biological sulfide oxidation within the biofilm. The nitrite uptake rate of the reactor increased over the nitrite dosing period and nitrous oxide production was observed within the biofilm. When nitrite addition was stopped, sulfate reduction and methane production gradually resumed, and reached pre-nitrite addition levels after 2.5 months. The slow recovery suggests that nitrite can be applied intermittently for sulfide and methane control, which represents a key advantage over similar chemicals such as nitrate and oxygen. The study demonstrates nitrite addition as a promising and effective strategy for the management of sulfide and methane in sewers. Further investigation and optimization are still required before application in the field.