Sage Journals: Discover world-class research

Abstract

Stormwater runoff from urban and agricultural watersheds carries nitrate, which is difficult to remove because it is highly soluble and thought to be relatively inert in abiotic processes such as ion exchange and sorption. Thus, current practice relies on denitrification to capture nitrate in stormwater treatment practices, requiring storage of captured stormwater, anaerobic conditions, and enough residence time for the bacteria to convert nitrate to nitrogen gas. The purpose of this research was to (1) quantify abiotic nitrate removal and removal capacity of two granular activated carbons (GACs), and (2) illustrate use of GACs in stormwater treatment practices. Batch and upflow column experiments found that two commercially available GACs captured nitrate abiotically, although competition between (bi)carbonate and nitrate limited removal of nitrate. Compared with removal of nitrate by denitrification, abiotic capture of nitrate during storm events requires less stormwater storage volume and less residence time to remove nitrate because it accumulates on the media as stormwater passes through the filter. This suggests that nitrate can be removed from stormwater with less storage and smaller treatment practices.

Get full access to this article

View all access options for this article.

References

Bhatnagar

, Ji

, Choi

Y.-H.

, Jung

, Lee

S.-H.

, Kim

S.-J.

, Lee

, Suk

, Kim

H.-S.

, Min

, Kim

S.-H.

, Jeon

B.-H.

, and Kang

J.-W.

(2008). Removal of nitrate from water by adsorption onto zinc chloride treated activated carbon. Separ. Sci. Technol., 43, 886.

Brezonik

P.L.

, and Arnold

W.A.

(2011). Water Chemistry: An Introduction to the Chemistry of Natural and Engineered Aquatic Systems. New York: Oxford University Press.

Brown

R.A.

, and Hunt

W.F.

(2011). Underdrain configuration to enhance bioretention exfiltration to reduce pollutant loads. J. Environ. Eng-ASCE., 137, 1082.

Carbon Resources. (2011). Technical Specifications: Granular Activated Carbon CR830A. Oceanside, CA: Carbon Resources, Inc. 2535 Jason Court. Available at: www.carbonresources.com. (accessed September 6, 2011).

Chatterjee

, and Woo

S.H.

(2009). The removal of nitrate from aqueous solutions by chitosan hydrogel beads. J. Hazard. Mater., 164, 1012.

Clark

S.E.

(1997). Stormwater Runoff Treatment by Filtration: A Pilot-Scale Study. Dissertation Research Proposal, Birmingham, AL: The University of Alabama at Birmingham.

Clark

S.E.

(2000). Urban Stormwater Filtration: Optimization of Design Parameters and a Pilot-Scale Evaluation. Ph.D. Department of Civil and Environmental Engineering. Birmingham, AL: The University of Alabama at Birmingham.

Clark

S.E.

, and Pitt

(2011). Filtered Metals Control in Stormwater using Engineered Media. Palm Springs, CA: World Environmental and Water Resources Congress. 2011.

Crittenden

J.C.

, Trussell

R.R.

, Hand

D.W.

, Howe

K.J.

, and Tchobanoglous

(2005). Water Treatment: Principles and Design. Hoboken, N.J: John Wiley, Montgomery Watson Harza.

10.

Demiral

, and Gunduzoglu

(2010). Removal of nitrate from aqueous solutions by activated carbon prepared from sugar beet bagasse. Bioresour. Technol., 101, 1675.

11.

Eaton

A.D.

, Clesceri

L.S.

, Greenberg

A.E.

, and Franson

M.A.H.

, American Public Health Association., American Water Works Association., & Water Environment Federation. (1998). Standard methods for the examination of water and wastewater. Washington, DC: American Public Health Association.

12.

Gao

B.Y.

, Wang

, Yue

Q.Y.

, Xu

, Yue

W.W.

, and Xu

X.M.

(2011). Adsorption kinetics of nitrate from aqueous solutions onto modified corn residue. Int. J. Environ. Poll., 45, 58.

13.

Hsieh

C.H.

, and Davis

A.P.

(2005). Evaluation and optimization of bioretention media for treatment of urban storm water runoff. J. Environ. Eng., 131, 1521.

14.

Kato

, Kuroda

, and Nakasone

(2009). Runoff characteristics of nutrients from an agricultural watershed with intensive livestock production. J. Hydrol., 368, 79.

15.

Kayhanian

, Fruchtman

B.D.

, Gulliver

J.S.

, Montanaro

, Ranieri

, and Wuertz

(2012). Review of highway runoff characteristics: Comparative analysis and universal implications. Water Res. 46, 6609.

16.

Kayhanian

, Suverkropp

, Ruby

, and Tsay

(2007). Characterization and prediction of highway runoff constituent event mean concentration. J. Environ. Manage., 85, 279.

17.

Kim

, Seagren

E.A.

, and Davis

A.P.

(2003). Engineered bioretention for removal of nitrate from stormwater runoff. Water Environ. Res., 75, 355.

18.

Luell

S.K.

, Hunt

W.F.

, and Winston

R.J.

(2011). Evaluation of undersized bioretention stormwater control measures for treatment of highway bridge deck runoff. Water Sci. Technol., 64, 974.

19.

Maestre

, and Pitt

(2005). The National Stormwater Quality Database, Version 1.1: A Compilation and Analysis of NPDES Stormwater Monitoring Information. University of Alabama, Center for Watershed Protection: Ellicott City, MA.

20.

Mizuta

, Matsumoto

, Hatate

, Nishihara

, and Nakanishi

(2004). Removal of nitrate-nitrogen from drinking water using bamboo powder charcoal. Bioresour. Technol., 95, 255.

21.

Norit Americas. (2012). Datasheet: Hydrodarco 3000 Granular Activated Carbon. Marshall, TX: Norit Americas, Inc. 3200 University Avenue. Available at: www.norit-americas.com (accessed July 12, 2012).

22.

Passeport

, Hunt

W.F.

, Line

D.E.

, Smith

R.A.

, and Brown

R.A.

(2009). Field study of the ability of two grassed bioretention cells to reduce storm-water runoff pollution. J. Irrig Drain Eng-ASCE., 135, 505.

23.

Paus

K.H.

, Morgan

, Gulliver

J.S.

, and Hozalski

R.M.

(2014a). Effects of bioretention media compost volume fraction on toxic metals removal, hydraulic conductivity, and phosphorous release. J. Environ. Eng., 140, 04014033.

24.

Paus

K.H.

, Morgan

, Gulliver

J.S.

, Leiknes

, and Hozalski

R.M.

(2014b). Effects of temperature and NaCl on toxic metal retention in bioretention media. J. Environ. Eng., 140, 04014034.

25.

Pitt

, Clark

S.E.

, and Steets

(2010a). Evaluation of the Contaminant Removal Potential of Biofiltration Media. 2010 International Low Impact Development Conference: Redefining Water in the City. San Francisco, CA.

26.

Pitt

, Clark

S.E.

, and Steets

(2010b). Laboratory Evaluations to Support the Design of Bioretention Systems in the Southwestern U.S. Providence, RI: World Environmental and Water Resources Congress. 2010.

27.

Pritzlaff

2003. Determination of nitrate/nitrite in surface and wastewaters by flow injection analysis. QuikChem ® Method 10-107-04-1-C. Loveland, CO: Lachat Instruments.

28.

Schueler

T.R.

, (1987). Controlling Urban Runoff; a Practical Manual for Planning and Designing Urban BMP's, Department of Environmental Programs. Washington, D.C: Metropolitan Washington Council of Governments.

29.

Smil

(2000). Cycles of Life: Civilization and the Biosphere. Henry Holt and Company.

30.

Stumm

, and Morgan

J.J.

(1981). Aquatic Chemistry: An Introduction Emphasizing Chemical Equilibria in Natural Waters. New York: Wiley.

31.

Stuntebeck

T.D.

, Komiskey

M.J.

, Peppler

M.C.

, Owens

D.W.

, and Frame

D.R.

(2011). Precipitation-runoff relations and water-quality characteristics at edge-of-field stations, Discovery Farms and Pioneer Farm, Wisconsin, 2003–2008, U.S. Geological Survey Scientific Investigations Report 2011–5008.

32.

U.S. EPA. (1999). Preliminary Data Summary of Urban Storm Water Best Management Practices EPA-821-R-99-012. Washington, D.C.: U.S. Environmental Protection Agency.

33.

U.S. EPA. (2000). Storm Water Phase II Final Rule: Fact Sheet 1.0. Washington, D.C.: U.S. Environmental Protection Agency.

34.

U.S. EPA. (2007). Hypoxia in the Northern Gulf of Mexico. Washington, D.C.: U.S. EPA Science Advisory Board Report EPA-SAB-08-003.

35.

U.S. EPA. (2012). Basic Information About Nitrate in Drinking Water. Available at: http://water.epa.gov/drink/contaminants/basicinformation/nitrate.cfm (accessed December 20, 2012).

36.

Zhang

X.L.

, Zhang

, He

, Cheng

S.P.

, Liang

, and Wu

Z.B.

(2007). Differentiate performance of eight filter media in vertical flow constructed wetland: Removal of organic matter, nitrogen and phosphorus. Fresen. Environ. Bull., 16, 1468.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.77 MB

Abiotic Capture of Stormwater Nitrates with Granular Activated Carbon

Abstract

Abstract

Get full access to this article

References

Supplementary Material