Efficiency of heavy metals removal during roof runoff infiltration through vegetated soil

• Autorzy: Sakson G.

Identyfikatory

DOI

10.5277/epe170309

• Języki publikacji: EN

Abstrakty

EN

Stormwater discharged from urban areas can contain significant amounts of heavy metals, especially zinc and copper. Roof runoff is very often directed into the soil and may pose a risk for groundwater quality. Lysimeter research has shown that zinc and copper contained in stormwater may be effectively removed by passing through vegetated soil. The average removal efficiency was greater than 90% and did not depend on the metal concentration in the influent, and the concentrations in the effluent met the limits for drinking water. Infiltration may be a reliable treatment method for roof runoff and may make stormwater safe for groundwater recharge.

Słowa kluczowe

EN

water treatment; cooper; groundwater; heavy metals; infiltration; soil

PL

uzdatnianie wody; miedź; wody gruntowe; metale ciężkie; infiltracja; gleba

• Wydawca: Oficyna Wydawnicza Politechniki Wrocławskiej
• Czasopismo: Environment Protection Engineering
• Rocznik: 2017
• Tom: Vol. 43, nr 3
• Strony: 143--154
• Opis fizyczny: Bibliogr. 25 poz., tab., rys.

Twórcy

autor

Sakson G.

• Łódź University of Technology, Institute of Environmental Engineering and Building Installations, 90-924 Łódź, al. Politechniki 6, Poland

Bibliografia

• [1] ZAWILSKI M., SAKSON G., Assessment of total suspended solid emission discharged via storm sewerage system from urban areas, Ochr. Śr., 2013, 35 (2), 33 (in Polish).
• [2] LANGEVELD J.G., LIEFTING H.J., BOOGAARD F.C., Uncertainties of stormwater characteristics and removal rates of stormwater treatment facilities: implications for stormwater handling, Water Res., 2012, 46 (20), 6868.
• [3] PITT R., CLARK S., FIELD R., Groundwater contamination potential from stormwater infiltration practices, Urban Water, 1999, 1 (3), 217.
• [4] ERIKSSON E., BAUN A., SCHOLES L., LEDIN A., AHLMAN S., REVITT M., NOUTSOPOULOS C., MIKKELSEN P.S., Selected stormwater priority pollutants – a European perspective, Sci. Total Environ., 2007, 383 (1–3), 41.
• [5] GREBEL J.E., MOHANTY S.K., TORKELSON A.A., BOEHM A.B., HIGGINS C.P., MAXWELL R.M., NELSON K.M., SEDLAK D.L., Engineered infiltration systems for urban stormwater reclamation, Environ. Eng. Sci., 2013, 30 (8), 437.
• [6] CHANG M., MCBROOM M.W., BREASLEY R.S., Roofing as a source of nonpoint water pollution, J. Environ. Manage., 2004, 73 (4), 307.
• [7] ZOBRIST J., MÜLLER S.R., AMMANN A., BUCHELI T.D., MOTTIER V., OCHS M., SCHOENENBERGER R., EUGSTER J., BOLLER M., Quality of roof runoff for groundwater infiltration, Water Res., 2000, 34 (5),.
• [8] ALI H., KHAN E., SAJAD M.A., Phytoremediation of heavy metals. Concepts and applications, Chemosphere, 2013, 91 (7), 869.
• [9] GROMAIRE M.C., WAINTROP N., CHEBBO G., CONSTANT A., Importance of zinc roofs in Paris and their impact on urban runoff pollutant loads, [in:] B. Chocat, M. Desbordes, Proc. 4th International Conference on Innovative Technologies in Urban Drainage Novatech, G.R.A.I.E. Villeurbanne, 2001, 937.
• [10] FIJAŁKOWSKI K., KACPRZAK M., GROBELAK A., PLACEK A., The influence of selected soil parameters on the mobility of heavy metals in soil, Inż. Ochr. Śr., 2012, 15 (1), 81.
• [11] GHOSH M., SINGH S.P., A review of phytoremediation of heavy metal and utilization of its byproducts, Appl. Ecol. Environ. Res., 2005, 3 (1), 1.
• [12] READ J., WEVILL T., FLETCHER T., DELETIC A., Variation among plant species in pollutant removal from stormwater in biofiltration systems, Water Res., 2008, 42 (4–5), 893.
• [13] SUN X., DAVIS A.P., Heavy metal fates in laboratory bioretention systems, Chemosphere, 2007, 66 (9),.
• [14] BLECKEN G.-T., ZINGER Y., DELETIĆ A., FLETCHER T.D., VIKLANDER M., Influence of intermittent wetting and drying conditions on heavy metal removal by stormwater biofilters, Water Res., 2009, 43 (18), 4590.
• [15] SØBERG L.C., VIKLANDER M., BLECKEN G.-T., The influence of temperaturę and salt on metal and sediment removal in stormwater biofilters, Water Sci. Technol., 2014, 69 (11), 2295
• [16] DAVIS A.P., SHOKOUHIAN M., SHARMA H., MINAMI C., Laboratory study of biological retention for urban stormwater management, Water Environ. Res., 2001, 73 (1), 5.
• [17] MASON Y., AMMANN A.A., ULRICH A., SIGG L., Behavior of heavy metals, nutrients and major components during roof runoff infiltration, Environ. Sci. Technol., 1999, 33 (10), 1588.
• [18] TROWSDALE S.A., SIMCOCK R., Urban stormwater treatment using bioretention, J. Hydrol., 2011, 397 (3–4), 167.
• [19] ZAWILSKI M., SAKSON G., BRZEZIŃSKA A., Opportunities for sustainable management of rainwater: case study of Łódź, Poland, Ecohydrol. Hydrobiol., 2014, 14 (3), 220.
• [20] SAKSON G., ZAWILSKI M., BRZEZIŃSKA A., Assessment of heavy metal loads emitted from urban catchment based on Lodz City, 13th International Conference on Urban Drainage, Sarawak, Malaysia, 7–12 September 2014.
• [21] WOŁEJKO E., WYDRO U., BUTAREWICZ A., ŁOBODA T., Effect of sewage sludge on the accumulation of heavy metals in soil and in mixtures of lawn grasses, Environ. Prot. Eng., 2013, 39 (2), 67.
• [22] ZGHEIB S., MOILLERON R., CHEBBO G., Priority pollutants in urban stormwater. Part 1. Case of separate storm sewers, Water Res., 2012, 46 (20), 6683.
• [23] BERT V., LORS C., LABOUDIGUE A., TACK K., DAMIDOT D., BUREAU J., Use of phytostabilisation to remediate metal polluted dredged sediment, N.-E. Abriak, D. Damidot, R. Zentar, International Symposium on Sediment Management (I2SM), July 2008, Lille, France, Mines de Doual, 275.
• [24] Overview of native plant species with remediation potential that have applicability to land rehabilitation objectives, Public Works Technical Bulletin 200-1-53, 30 November 2007, http://www.wbdg. org/ccb/browse_cat.php?o=31&c=215
• [25] SØBERG L.C., HEDSTROM A., BLECKEN G.-T., VIKLANDER M., Metal uptake in three different plant species used for cold climate biofilter sustems, 13th International Conference on Urban Drainage, Sarawak, Malaysia, 7–12 September 2014.