Phosphorus removal by laboratory-scale unvegetated vertical-flow constructed wetland systems using anthracite, steel slag and related blends as substrate

Water Science and Technology

Volumn 63, Issue 11, 2011, Pages 2719-2724

  Wu, Junmei ^a,b   He, Feng ^a   Xu, Dong ^a   Wang, Rong ^a,b   Zhang, Xiangling ^c   Xiao, Enrong ^a   Wu, Zhenbin ^a  

^a INSTITUTE OF HYDROBIOLOGY   (China)

^b UNIVERSITY OF CHINESE ACADEMY OF SCIENCES   (China)

^c WUHAN UNIVERSITY OF TECHNOLOGY   (China)

Author keywords

Anthracite; Phosphorus removal; Steel slag; Substrate

Indexed keywords

DOMESTIC SEWAGE; ENVIRONMENTAL REQUIREMENT; HIGH EFFICIENCY; LABORATORY SCALE; LOADING RATE; LONG TERM PERFORMANCE; LOW CONCENTRATIONS; P REMOVAL; PHOSPHORUS REMOVAL; SOLUBLE REACTIVE P; STEEL SLAG; SUBSTRATE SYSTEM; THREE SYSTEMS; TOPDOWN; VERTICAL FLOW CONSTRUCTED WETLANDS;

ANTHRACITE; CLAY MINERALS; PH EFFECTS; PHOSPHORUS; SEWAGE; SEWAGE TREATMENT; SLAGS; WETLANDS;

SUBSTRATES;

ANTHRACITE; INDUSTRIAL CHEMICAL; PHOSPHORUS; UNCLASSIFIED DRUG;

ANTHRACITE; CONSTRUCTED WETLAND; DOMESTIC WASTE; FLOW MODELING; LABORATORY METHOD; PERFORMANCE ASSESSMENT; PH; PHOSPHORUS; POLLUTANT REMOVAL; SEWAGE; SLAG; STEEL; SUBSTRATE;

ADSORPTION; ARTICLE; CONSTRUCTED WETLAND; INDUSTRIAL WASTE; LABORATORY; PH; REDUCTION; SEWAGE EFFLUENT; SEWAGE TREATMENT; STEEL SLAG; WASTE COMPONENT REMOVAL; WASTE WATER MANAGEMENT;

COAL; HYDROGEN-ION CONCENTRATION; PHOSPHORUS; STEEL; TIME FACTORS; WASTE DISPOSAL, FLUID; WATER POLLUTANTS, CHEMICAL; WATER PURIFICATION; WETLANDS;

CHINA;

EID: 79959291016     PISSN: 02731223     EISSN: None     Source Type: Journal    
DOI: 10.2166/wst.2011.573     Document Type: Article

References (17)

1. Agyei, N. M., Strydom, C. A. & Potgieter, J. H. 2002 The removal of phosphate ions from aqueous solution by fly ash, slag, ordinary Portland cement and related blends. Cement and Concrete Research 32, 1889-1897. (Pubitemid 35282097)
2. Babatunde, A. O. & Zhao, Y. Q. 2009 Phosphorus removal in laboratory-scale unvegetated vertical subsurface flow constructed wetland systems using alum sludge as main substrate. Water Science and Technology 60 (2), 483-489.
3. Bowden, L. I., Jarvis, A. P., Younger, P. L. & Johnson, K. L. 2009 Phosphorus removal from waste waters using basic oxygen steel slag. Environmental Science and Technology 43, 2476-2481.
4. Drizo, A., Forget, C., Chapuis, R. P. & Comeau, Y. 2006 Phosphorus removal by electric arc furnace steel slag and serpentinite. Water Research 40, 1547-1554.
5. Johansson, L. 1999 Blast furnace slag as phosphorus sorbents - column studies. The Science of the Total Environment 229, 89-97. (Pubitemid 29240681)
6. Johansson, L. & Gustafsson, J. P. 2002 Phosphate removal using blast furnace slags and opaka-mechanisms. Water Research 34 (1), 259-265.
7. Kõiv, M., Vohla, C., Mõtlep, R., Liira, M., Kirsimäe, K. & Mander, Ü. 2009 The performance of peat-filled subsurface flow filers treating landfill leachate and municipal wastewater. Ecological Engineering 35, 204-212.
8. Lee, M. S., Drizo, A., Rizzo, D. M., Druschel, G., Hayden, N. & Twohig, E. 2010 Evaluating the efficiency and temporal variation of pilot-scale constructed wetlands and steel slag phosphorus removing filters for treating dairy wastewater. Water Research 44, 4077-4086.
9. Mann, R. A. 1997 Phosphorous adsorption and desorption characteristics of constructed wetland gravels and steelworks by-products. Australian Journal of Soil Research 35, 375-384.
10. McDowell, R. W. 2004 The effectiveness of industrial by-products to stop phosphorous loss from a Pallic soil. Australian Journal of Soil Research 42, 755-761. (Pubitemid 39661314)
11. MEPPRC & AQSIQ 2002 Discharge Standard of Pollutants for Municipal Wastewater Treatment Plant (GB18918-2002). Ministry of Environmental Protection of the People's Republic of China (MEPPRC) & State General Administration of the People's Republic of China for Quality Supervision and Inspection and Quarantine (AQSIQ), Beijing, China. Available from: http://kjs.mep.gov.cn/ hjbhbz/bzwb/shjbh/swrwpfbz/200307/t20030701-66529.htm (accessed 28 February 2011).
12. Richardson, C. J. 1985 Mechanisms controlling phosphorus retention capacity in freshwater wetlands. Science 288, 1424-1427.
13. Rizzuti, A. M., Cohen, A. D., Hunt, P. G. & Ellison, A. Q. 2002 Retention of nitrogen and phosphorous from liquid swine and poultry manures using highly characterized peats. Journal of Environmental Science and Health B37 (6), 587-611. (Pubitemid 35191295)
14. Wu, J. M., Wang, R., Xu, D., Zhang, X. L., He, F. & Wu, Z. B. 2010 Long term performance of pilot-scale vertical flow constructed wetland using different substrates. China Environmental Science 30 (5), 633-638.
15. Zhang, D. Q., Gersberg, M. R. & Keat, S. T. 2009 Constructed wetlands in China. Ecological Engineering 35, 1367-1378.
16. Zhang, X. L., Zhang, S., He, F., Cheng, S. P., Liang, W. & Wu, Z. B. 2007 Differentiate performance of eight filter media in vertical flow constructed wetland: Removal of organic matter, nitrogen and phosphorus. Fresenius Environmental Bulletin 16 (11b), 1468-1473.
17. Zhao, Y. Q., Zhao, X. H. & Babatunde, A. O. 2009 Use of dewatered alum sludge as main substrate in treatment reed bed receiving agricultural wastewater: Long-term trial. Bioresource Technology 100, 644-648.