Role of extracellular exopolymers on biological phosphorus removal

Journal of Environmental Sciences

Volumn 18, Issue 4, 2006, Pages 670-674

  Liu, Ya Nan ^a   Xue, Gang ^a   Yu, Shui Li ^b   Zhao, Fang Bo ^b  

^a DONGHUA UNIVERSITY   (China)

^b HARBIN INSTITUTE OF TECHNOLOGY   (China)

Author keywords

Biological phosphorus removal; Biosorption; Extracellular exopolymers

Indexed keywords

BIOLOGICAL PHOSPHORUS REMOVAL; BIOSORPTION EFFECT; EXTRACELLULAR EXOPOLYMERS; SEQUENCING BATCH REACTORS;

BIOREACTORS; GLUCOSE; PHOSPHORUS; REMOVAL; SEWAGE SLUDGE;

BIOLOGICAL SEWAGE TREATMENT;

BACTERIAL POLYSACCHARIDE; BIOPOLYMER; PHOSPHORUS;

BIOLOGICAL SEWAGE TREATMENT; BIOREACTORS; GLUCOSE; PHOSPHORUS; REMOVAL; SEWAGE SLUDGE;

BIOREACTOR; ELECTRON MICROSCOPY; EXOPOLYMER; PHOSPHORUS; REMOVAL EXPERIMENT; SORPTION; SPECTROMETRY;

ADSORPTION; ARTICLE; BACTERIUM; BIOREACTOR; BIOREMEDIATION; CHEMISTRY; MASS SPECTROMETRY; METABOLISM; METHODOLOGY; MICROBIOLOGY; SCANNING ELECTRON MICROSCOPY; SEWAGE;

ADSORPTION; BACTERIA; BIODEGRADATION, ENVIRONMENTAL; BIOPOLYMERS; BIOREACTORS; MASS SPECTROMETRY; MICROSCOPY, ELECTRON, SCANNING; PHOSPHORUS; POLYSACCHARIDES, BACTERIAL; SEWAGE; WASTE DISPOSAL, FLUID;

EID: 33749330534     PISSN: 10010742     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Article

References (15)

1. Che O J, Jone M P, 2000. Enhanced biological phosphorus removal in a sequencing batch reactor supplied with glucose as a sole carbon source[J]. Wat Res, 34: 2160-2170.
2. Cloete T E, Oosthuizen D J, 2001. The role of extracellular exopolymers; in the removal of phosphorus from activated sludge [J]. Wat Res, 35: 3595-3598.
3. Frolund B, Palmgren R, Keiding K et al., 1996. Extraction of extracellular sludge using cation exchange resin [J]. Wat Res, 33: 1749-1758.
4. Görner T, Philippe D, Marie H A, 2003. Activated sludge exopolymers: separation and identification using size exclusion chromatography and infrared micro-spectroscopy [J]. Wat Res, 37: 2388-2393.
5. Heymann J H, Eagle L M, Greben H A et al., 1989. The isolation and characterization of volutin granules as subcellulair components involved in biological phosphorus removal [J]. War Sci & Tech, 21(5/6); 397-408.
6. Jorand F, Zartarian F, Thomas F et al., 1995. Chemical and structural (2D) linkage between bacteria within activated sludge flocs [J]. War Res, 29: 1639-1647.
7. Liao B Q, Allen D G, Droppo G et al., 2001. Suiface properties of sludge and their role in bioflocculation and settleability [J]. Wat Res, 35: 339-350.
8. Lin C K, Katayama. Y, Hosomi M et al., 2003. The characteristics of the bacterial community structure and population dynamics for phosphorus removal in SBR activated sludge processes [J]. Wat Res, 37: 2944-2952.
9. Liu W T, Katrina D, Nakamura K et al., 2000. Microbial community changes in biological phosphate-removal systems on altering sludge phosphorus content [J]. Environ Microbio, 146: 1099-1107.
10. Loaëc M, Olier R, Guezennecc J, 1997. Uptake of lead cadmium and zinc by a novel bacterial exopolysaccharide [J]. Wat Res, 31: 1171-1179.
11. Randall A A, Liu Y H, 2002. Polyhydroxyalkanoates form potentially a key aspect of aerobic phosphorus uptake in enhanced biological phosphorus removal[J]. Wat Res, 36: 3473-3478.
12. SEPAC, 1989. Water and wastewater analytical methods M. Beijing, China Environmental Science Press, The third version: 280-285; 354-356.
13. Sudiana I M, Mino T, Satoh H et al., 1999. Metabolism of enhanced biological phosphorus removal and non-enhanecd biological phosphorus removal sludge with acetate and glucose as carbon source[J]. Wat Sci and Tech, 39: 29-35.
14. Wang N D, 2001. Experimental study and mathematical modeling of enhanced biolog0cal phosphorus removal using glucose as the dominant substrate[D]. University of Saskatchewan, Canada.
15. Wang N D, Peng J, Gordon H, 2002. Biochemical model of glucose induced enhanced biological phosphorus removal under anaerobic condition[J]. Wat Res, 36: 49-58.