Environmental Engineering Reference
In-Depth Information
Acknowledgment
The authors are grateful for the inancial support provided by SBIR grants from the
National Science Foundation and a Third Frontier grant from the Ohio Department of
Development. The authors want to recognize the signiicant contributions made by many
of the MetaMateria staff and students at Michigan State University, as well as the guidance
offered by engineering and consulting irms helping to evaluate the phosphorus media.
References
Bachand, P.A.M. 2003. Potential Application of Adsorptive Media to Enhance Phosphorus.
Brix, H., Arias, C.A., and del Bubba, M. 2001. Media selection for sustainable phosphorus removal in
subsurface low constructed wetlands.
Water Science and Technology
44(11-12): 47-54.
Camm, E. 2011. An evaluation of engineered media for phosphorus removal from greenroof storm-
water runoff, MS Thesis, University of Waterloo, Waterloo, Ontario, Canada, 2011.
Centre Européen d'Estudes des Polyphosphates (CEEP). September 2012.
SCOPE Newsletter
, p. 6.
Cheung, K.C., and Venkitachalam, T.H. 2000. Improving phosphate removal of sand iniltration sys-
tem using alkaline ly ash.
Chemosphere
41: 243-249.
Clabby, C. 2010. Does peak phosphorous loom?
American Scientist
98(4): 291.
Drizo, A., Frost, C.A., Grace, J., and Smith, K.A. 1999. Physico-chemical screening of phosphate
removing substrates for use in constructed wetland systems.
Water Research
17: 3595-3602.
Helferich, R. July 2011. Final Report to National Science Foundation, Phase I SBIR Wastewater
Phosphorus Removal using Nano Enhanced Reactive Iron Media.
Johansson, L., and Gustafsson, J.P. 2000. Phosphate removal by using blast furnace slags and opoka-
mechanisms.
Water Research
34(1): 259-265.
Kasprzyk-Holdern, B. 2004. Chemistry of alumina, reactions in aqueous solution and its application
in water treatment.
Advances in Colloid and Interface Science
110: 19-48.
Kim, J., Ma, J., Howerter, K., Garofalo, H., and Sansalone, J. 2008. Interactions of phosphorus with
anthropogenic and engineered particulate matter as a function of mass, number and surface
area. In: W. James, K.N. Irvine, E.A. McBean, R.E. Pitt, and S.J. Wright (eds.)
Reliable Modeling of
Urban Water Systems, Monograph 16
. CHI, Guelph, Ontario.
Krögera, R., Dunne, E.J., Novak, J., King, K.W., McLellan, D.E., Smith, D.R., Strock, J., Boomer, K.,
Tomer, M., and Noe, G.B. 2012. Downstream approaches to phosphorus management in agri-
cultural landscapes: Regional applicability and use.
Science of the Total Environment
442(2013):
263-274.
Littleton, H.X., Daigger, G.T., and Strom, P.F. 2007. Application of computational luid dynamics to
closed loop bioreactors: I. Characterization and simulation of luid low pattern and oxygen
transfer.
Water Environment Research
79(6): 600-612.
Littleton, H.X., Daigger, G.T., Strom, P.F., and Cowan, R.M. 2000. Evaluation of autotrophic denitri-
ication and heterotrophic nitriication in simultaneous biological nutrient removal systems.
Proceedings, WEFTEC 2000, 73rd Annual Conference
, Water Environment Federation, Anaheim,
CA, Session 19, 21 pp. [CD-ROM].
Littleton, H.X., Daigger, G.T., Strom, P.F., and Cowan, R.M. 2002a. Evaluation of autotrophic deni-
triication, heterotrophic nitriication, and PAOs in full scale simultaneous biological nutrient
removal systems.
Water Science & Technology
46(1-2): 305-312.
Littleton, H.X., Daigger, G.T., Strom, P.F., and Cowan, R.A. 2003a. Evaluation of autotrophic denitri-
ication, heterotrophic nitriication, and biological phosphorus removal in full scale simulta-
neous biological nutrient removal systems.
Water Environment Research
75: 138-150.
