Effect of hydraulic retention time on sulfate reduction in a carbon monoxide fed thermophilic gas lift reactor

Water Research

Volumn 41, Issue 9, 2007, Pages 1995-2003

  Sipma, Jan ^a   Begona Osuna M ^a   Lettinga, Gatze ^a   Stams, Alfons J M ^a   Lens, Piet N L ^a  

^a WAGENINGEN UNIVERSITY   (Netherlands)

Author keywords

Carbon monoxide; Gas lift reactors; Hydrogen; Hydrogenogenesis; Methanogenesis; Sulfate reduction

Indexed keywords

BIOMASS; CARBON MONOXIDE; CHEMICAL REACTORS; HYDROGEN; MICROORGANISMS; SEWAGE SLUDGE;

GAS LIFT REACTORS; HYDROGENOGENESIS; METHANOGENESIS; SULFATE REDUCTION;

ANAEROBIC DIGESTION;

CARBON MONOXIDE; SULFATE;

ANAEROBIC DIGESTION; BIOMASS; CARBON MONOXIDE; CHEMICAL REACTORS; HYDROGEN; MICROORGANISMS; SEWAGE SLUDGE;

ANOXIC CONDITIONS; BIOMASS; CARBON MONOXIDE; HYDROGEN; METHANOGENESIS; MICROBIAL ACTIVITY; REDUCTION; RETENTION; SLUDGE; SULFATE;

ANAEROBIC METABOLISM; ARTICLE; BIOREACTOR; ELECTRON TRANSPORT; HYDRAULIC CONDUCTIVITY; HYDROGENATION; PRIORITY JOURNAL; REDUCTION;

EID: 34047132232     PISSN: 00431354     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.watres.2007.01.030     Document Type: Article

References (24)

1. Chuichulcherm S., Nagpal S., Peeva L., and Livingston A. Treatment of metal-containing wastewaters with a novel extractive membrane reactor using sulfate-reducing bacteria. J. Chem. Technol. Biotechnol. 76 (2001) 61-68
2. Davidova M.N., Tarasova N.B., Mukhitova F.K., and Karpilova I.U. Carbon monoxide in metabolism of anaerobic bacteria. Can. J. Microbiol. 40 (1994) 417-425
3. De Smul A., and Verstraete W. The phenomenology and the mathematical modeling of the silicone-supported chemical oxidation of aqueous sulfide to elemental sulfur with ferric sulfate. J. Chem. Technol. Biotechnol. 74 (1999) 456-466
4. Du Preez L.A., and Maree J.P. Pilot-scale biological sulphate and nitrate removal utilizing producer gas as energy source. Water Sci. Technol. 30 (1994) 275-285
5. 2 from gas streams. In: Lens P.N.L., and Hulshoff Pol L.W. (Eds). Environmental Technologies to Treat Sulfur Pollutions; Principles and Engineering (2000), IWA Publishing, London 265-280
6. Mörsdorf G., Frunzke K., Gadkari D., and Meyer O. Microbial growth on carbon monoxide. Biodegradation 3 (1992) 61-82
7. Oh S.-E., Van Ginkel S., and Logan B.E. The relative effectiveness of pH control and heat treatment for enhancing biohydrogen gas production. Environ. Sci. Technol. 37 (2003) 5186-5190
8. Oremland R.S., and Capone D.G. Use of "specific" inhibitors in biogeochemistry and microbial ecology. Adv. Microb. Ecol. 10 (1988) 285-383
9. Parshina S.N., Kijlstra S., Henstra A.M., Sipma J., Plugge C.M., and Stams A.J.M. Carbon monoxide conversion by thermophilic sulfate-reducing bacteria in pure culture and in co-culture with Carboxydothermus hydrogenoformans. Appl. Microbiol. Biotechnol. 68 3 (2005) 390-396
10. Parshina S.N., Sipma J., Nakashimada Y., Henstra A.M., Smidt H., Lysenko A.M., Lens P.N.L., Lettinga G., and Stams A.J.M. Desulfotomaculum carboxydivorans sp. nov., a novel sulfate-reducing bacterium capable of growth at 100% CO. Int. J. System. Evol. Microbiol. 55 (2005) 2159-2165
11. Perry R.H., Green D.W., and Maloney J.O. Perry's Chemical Engineers' Handbook. 7th ed (1997), McGraw-Hill, New York, USA
12. Sipma J., Meulepas R.J.W., Parshina S.N., Stams A.J.M., Lettinga G., and Lens P.N.L. Effect of carbon monoxide, hydrogen and sulfate on thermophilic (55 °C) hydrogenogenic carbon monoxide conversion in two anaerobic bioreactor sludges. Appl. Microbiol. Biotechnol. 64 (2004) 421-428
13. 2. Biotechnol. Progr. 22 (2006) 1327-1334
14. Sipma J., Henstra A.M., Parshina S.N., Lens P.N.L., Lettinga G., and Stams A.J.M. Microbial CO conversions with applications in synthesis gas purification and bio-desulfurization. Crit. Rev. Biotechnol. 26 1 (2006) 41-65
15. Stams A.J.M., Van Dijk J.B., Dijkema C., and Plugge C.M. Growth of syntrophic propionate-oxidizing bacteria with fumarate in the absence of methanogenic bacteria. Appl. Environ. Microbiol. 59 (1993) 1114-1119
16. Trüper H.G., and Schlegel H.G. Sulphur metabolism in Thiorhodaceae-I, Quantitative measurements on growing cells of Chromatium okenii. Antonie van Leeuwenhoek (J. Microbiol. Serol.) 30 (1964) 225-238
17. Vallero M.V.G., Treviño R.H.M., Paulo P.L., Lettinga G., and Lens P.N.L. Effect of sulfate on methanol degradation in thermophilic (55 °C) methanogenic UASB reactors. Enzyme Microb. Technol. 32 6 (2003) 676-687
18. Vallero M.V.G., Lettinga G., and Lens P.N.L. High rate sulfate reduction in a submerged anaerobic membrane bioreactor (SAMBaR) at high salinity. J. Membrane Sci. 253 (2005) 217-232
19. Van Houten R.T., and Lettinga G. Biological sulphate reduction with synthesis gas: microbiology and technology. In: Wijffels R.H., Buitelaar R.M., Bucke C., and Tramper J. (Eds). Progress in Biotechnology vol. 11 (1996), Elsevier, Amsterdam 793-799
20. Van Houten R.T., Oude Elferink S.J.W.H., Van Hamel S.E., Hulshoff Pol L.W., and Lettinga G. Sulphate reduction by aggregates of sulphate-reducing bacteria and homo-acetogenic bacteria in a lab-scale gas-lift reactor. Biores. Technol. 54 (1995) 73-79
21. Van Houten R.T., Van der Spoel H., Van Aelst A.C., Hulshoff Pol L.W., and Lettinga G. Biological sulphate reduction using synthesis gas as energy and carbon source. Biotechnol. Bioeng. 50 (1996) 136-144
22. 2 as energy and carbon source. Biotechnol. Bioeng. 55 (1997) 807-814
23. Weijma J., Stams A.J.M., Hulshoff Pol L.W., and Lettinga G. Thermophilic sulfate reduction and methanogenesis with methanol in a high rate anaerobic reactor. Biotechnol. Bioeng. 67 (2000) 354-363
24. Widdel F., and Hansen T.A. The dissimilatory sulfate- and sulfur-reducing bacteria. In: Balows A., Trüper H.G., Dworkin M., Harder W., and Schleifer K.-H. (Eds). The Prokaryotes. second ed (1991), Springer, New York 583-624