On the potential of on-line free-surface constructed wetlands for attenuating pesticide losses from agricultural land to surface waters
Andre Ramos A , Michael J. Whelan C E , Ian Guymer D , Raffaella Villa A B and Bruce Jefferson AA Water Sciences Institute, Cranfield University, Bedford, MK43 0AL, UK.
B Present address: Department of Engineering and Sustainable Development, De Montfort University, Leicester, LE1 9BH, UK.
C Centre for Landscape and Climate Research, University of Leicester, Leicester, LE1 7RH, UK.
D Department of Civil Engineering, University of Sheffield, Sheffield, S10 2TN, UK.
E Corresponding author. Email: mjw72@le.ac.uk
Environmental Chemistry 16(8) 563-576 https://doi.org/10.1071/EN19026
Submitted: 1 February 2019 Accepted: 3 May 2019 Published: 31 May 2019
Environmental context. Pesticide losses from land to surface waters have the potential to cause ecological damage. Furthermore, pesticides in surface waters present a major challenge for water companies accessing these waters for the domestic supply, in terms of complying with water quality regulations. Here, we evaluate the potential of field- and ditch-scale free-surface constructed wetland systems for reducing pesticide transfers from land to surface waters.
Abstract. Pesticides make important contributions to agriculture but losses from land to water can present problems for environmental management, particularly in catchments where surface waters are abstracted for drinking water. ‘On-line’ constructed wetlands have been proposed as a potential means of reducing pesticide fluxes in drainage ditches and headwater streams. Here, we evaluate the potential of two free-surface constructed wetland systems to reduce pesticide concentrations in surface waters using a combination of field monitoring and dynamic fugacity modelling. We specifically focus on metaldehyde, a commonly used molluscicide that is moderately mobile and has been regularly detected at high concentrations in drinking water supply catchments in the UK over the past few years. We also present data for the herbicide metazachlor. Metaldehyde losses from the upstream catchment were significant, with peak concentrations occurring in the first storm events in early autumn, soon after application. Concentrations and loads appeared to be minimally affected by transit through the monitored wetlands over a range of flow conditions. This was probably due to short solute residence times (quantified via several tracing experiments employing rhodamine WT – a fluorescent dye) exacerbated by solute exclusion phenomena resulting from patchy vegetation. Model analyses of different scenarios suggested that, even for pesticides with short aquatic half-lives, wetland systems would need to exhibit much longer residence times (RTs) than those studied here in order to deliver any appreciable attenuation. If the ratio of wetland surface area to the area of the contributing catchment is assumed to be a surrogate for RT (i.e. not accounting for solute exclusion), then model predictions suggest that this needs to be greater than 1 % to yield load reductions of 3 and 7 % for metaldehyde and metazachlor respectively.
References
Beer T, Young PC (1983). Longitudinal dispersion in natural streams. Journal of Environmental Engineering 109, 1049–1067.| Longitudinal dispersion in natural streamsCrossref | GoogleScholarGoogle Scholar |
Boeije GM, Schowanek D, Vanrolleghem P (2000). Incorporation of biofilm activity in instream biodegradation modeling: a case study for LAS. Water Research 34, 1479–1486.
| Incorporation of biofilm activity in instream biodegradation modeling: a case study for LASCrossref | GoogleScholarGoogle Scholar |
Brock TC, Arts GH, Maltby L, van den Brink PJ (2006). Aquatic risks of pesticides, ecological protection goals, and common aims in European Union Legislation. Integrated Environmental Assessment and Management 2, e20–e46.
| Aquatic risks of pesticides, ecological protection goals, and common aims in European Union LegislationCrossref | GoogleScholarGoogle Scholar |
Carty A, Scholz M, Heal K, Gouriveau F, Mustafa A (2008). The universal design, operation and maintenance guidelines for farm constructed wetlands (FCW) in temperate climates. Bioresource Technology 99, 6780–6792.
| The universal design, operation and maintenance guidelines for farm constructed wetlands (FCW) in temperate climatesCrossref | GoogleScholarGoogle Scholar | 18359625PubMed |
Centre for Ecology and Hydrology (CEH) (2001). Pesticide movement to surface waters at the catchment scale. Phase I: The role of ditches/small streams. MAFF Final Report PL0518. Ministry for Agriculture, Fisheries and Food, London, UK.
Cooper RJ, Fitt P, Hiscock KM, Lovett AA, Gumm L, Dugdale SJ, Rambohul J, Williamson A, Noble L, Beamish J, Hovesen P (2016). Assessing the effectiveness of a three-stage on-farm biobed in treating pesticide-contaminated wastewater. Journal of Environmental Management 181, 874–882.
| Assessing the effectiveness of a three-stage on-farm biobed in treating pesticide-contaminated wastewaterCrossref | GoogleScholarGoogle Scholar | 27397841PubMed |
Cranfield University (2017). The soils guide (Cranfield University: Cranfield). Available at www.landis.org.uk [Verified 8 March 2017]
Dolan T, Howsam P, Parsons DJ, Whelan MJ (2014). Impact of European Water Framework Directive Article 7 on Drinking Water Directive compliance for pesticides: challenges of a prevention-led approach. Water Policy 16, 280–297.
| Impact of European Water Framework Directive Article 7 on Drinking Water Directive compliance for pesticides: challenges of a prevention-led approachCrossref | GoogleScholarGoogle Scholar |
Environment Agency (2009). The determination of metaldehyde in waters using chromatography with mass spectrometric detection (Standing Committee of Analysts, Environment Agency National Laboratory Service: Rothley, Leicestershire, UK).
European Commission (EC) (1998). Council Directive 98/83/EC on the quality of water intended for human consumption. Official Journal of the European Communities L330/32 (EC: Brussels, Belgium).
European Commission (EC) (2000). Directive 2000/60/EC establishing a framework for community action in the field of water policy. Official Journal of the European Communities L 327/1–72 (EC: Brussels, Belgium).
European Food Safety Authority (EFSA) (2010). Conclusion on the peer review of the pesticide risk assessment of the active substance metaldehyde. EFSA Journal 8, 1856
| Conclusion on the peer review of the pesticide risk assessment of the active substance metaldehydeCrossref | GoogleScholarGoogle Scholar |
Fenner K, Lanz V, Scheringer M, Borsuk M (2007). Relating atrazine degradation rate in soil to environmental conditions: implications for global fate modeling. Environmental Science & Technology 41, 2840–2846.
| Relating atrazine degradation rate in soil to environmental conditions: implications for global fate modelingCrossref | GoogleScholarGoogle Scholar |
Fox KK, Holt M, Daniel M, Buckland H, Guymer I (2000). Removal of linear alkylbenzene sulfonate from a small Yorkshire stream. The Science of the Total Environment 251–252, 265–275.
| Removal of linear alkylbenzene sulfonate from a small Yorkshire streamCrossref | GoogleScholarGoogle Scholar |
Gregoire C, Elsaesser D, Huguenot D, Lange J, Lebeau T, Merli A, Mose R, Passeport E, Payraudeau S, Schutz T, Schulz R, Tapia-Padila G, Tournebize J, Trevisan M, Wanko A (2009). Mitigation of agricultural non-point-source pesticide pollution in artificial wetland ecosystems. Environmental Chemistry Letters 7, 205–231.
| Mitigation of agricultural non-point-source pesticide pollution in artificial wetland ecosystemsCrossref | GoogleScholarGoogle Scholar |
Hashemi F, Olesen JE, Børgesen CD, Tornbjerg H, Thodsen H, Dalgaard T (2018). Potential benefits of farm-scale measures versus landscape measures for reducing nitrate loads in a Danish catchment. The Science of the Total Environment 637–638, 318–335.
| Potential benefits of farm-scale measures versus landscape measures for reducing nitrate loads in a Danish catchmentCrossref | GoogleScholarGoogle Scholar | 29751312PubMed |
Kay P, Grayson R (2014). Using water industry data to assess the metaldehyde pollution problem. Water and Environment Journal 28, 410–417.
Klaus J, Zehe E, Elsner M, Külls C, McDonnell JJ (2013). Macropore flow of old water revisited: experimental insights from a tile-drained hillslope. Hydrology and Earth System Sciences 17, 103–118.
| Macropore flow of old water revisited: experimental insights from a tile-drained hillslopeCrossref | GoogleScholarGoogle Scholar |
Krogseth IS, Whelan MJ, Christensen GN, Breivik K, Evenset A, Warner NA (2017). Understanding of cyclic volatile methyl siloxane fate in a high-latitude lake is constrained by uncertainty in organic carbon–water partitioning. Environmental Science & Technology 51, 401–409.
| Understanding of cyclic volatile methyl siloxane fate in a high-latitude lake is constrained by uncertainty in organic carbon–water partitioningCrossref | GoogleScholarGoogle Scholar |
Levenspiel O (1972). ‘Chemical reaction engineering, 2nd edn.’ (John Wiley and Sons: Chichester)
Lu Q, Whitehead PG, Bussi G, Futter MN, Nizzetto L (2017). Modelling metaldehyde in catchments: a River Thames case study. Environmental Science. Processes & Impacts 19, 586–595.
| Modelling metaldehyde in catchments: a River Thames case studyCrossref | GoogleScholarGoogle Scholar |
Mackay D (2001). ‘Multimedia environmental models: the fugacity approach, 2nd edn.’ (CRC Press: Boca Raton, FL)
Mackay D, Joy M, Paterson S (1983). A quantitative water, air, sediment interaction (QWASI) fugacity model for describing the fate of chemicals in lakes. Chemosphere 12, 981–997.
| A quantitative water, air, sediment interaction (QWASI) fugacity model for describing the fate of chemicals in lakesCrossref | GoogleScholarGoogle Scholar |
McAvoy DC, Masscheleyn P, Peng C, Morrall SW, Casilla AB, Lim JMU, Gregorio EG (2003). Risk assessment approach for untreated wastewater using the QUAL2E water quality model. Chemosphere 52, 55–66.
| Risk assessment approach for untreated wastewater using the QUAL2E water quality modelCrossref | GoogleScholarGoogle Scholar | 12729687PubMed |
Mohamad Ibrahim IH, Gilfoyle L, Reynolds R, Voulvoulis N (2019). Integrated catchment management for reducing pesticide levels in water: engaging with stakeholders in East Anglia to tackle metaldehyde. The Science of the Total Environment 656, 1436–1447.
| Integrated catchment management for reducing pesticide levels in water: engaging with stakeholders in East Anglia to tackle metaldehydeCrossref | GoogleScholarGoogle Scholar | 30625671PubMed |
Moore MT, Rodgers JH, Cooper CM, Smith S (2000). Constructed wetlands for mitigation of atrazine-associated agricultural runoff. Environmental Pollution 110, 393–399.
| Constructed wetlands for mitigation of atrazine-associated agricultural runoffCrossref | GoogleScholarGoogle Scholar | 15092818PubMed |
Moore MT, Schulz R, Cooper CM, Smith S, Rodgers JH (2002). Mitigation of chlorpyrifos runoff using constructed wetlands. Chemosphere 46, 827–835.
| Mitigation of chlorpyrifos runoff using constructed wetlandsCrossref | GoogleScholarGoogle Scholar | 11922063PubMed |
Moore MT, Cooper CM, Smith S, Callum RF, Knight SS, Locke MA, Bennett ER (2009). Mitigation of two pyrethroid insecticides in a Mississippi Delta constructed wetland. Environmental Pollution 157, 250–256.
| Mitigation of two pyrethroid insecticides in a Mississippi Delta constructed wetlandCrossref | GoogleScholarGoogle Scholar | 18789833PubMed |
Newman JR, Duenas-Lopez MA, Acreman M, Palmer-Felgate EJ, Verhoeven JTA, Scholz M, Maltby E (2015). Do on-farm natural, restored, managed and constructed wetlands mitigate agricultural pollution in Great Britain and Ireland? A report of research carried out by the Centre for Ecology & Hydrology on behalf of the Department for Environment, Farming and Rural Affairs, with support from the Natural Environment Research Council (NERC). Defra Report No. WT0989, London, UK.
Passeport E, Tournebize J, Chaumont C, Guenne A, Coquet Y (2013). Pesticide contamination interception strategy and removal efficiency in forest buffer and artificial wetland in a tile-drained agricultural watershed. Chemosphere 91, 1289–1296.
| Pesticide contamination interception strategy and removal efficiency in forest buffer and artificial wetland in a tile-drained agricultural watershedCrossref | GoogleScholarGoogle Scholar | 23535469PubMed |
PPDB (2016). The Pesticide Properties Database (Agriculture & Environment Research Unit: University of Hertfordshire). Available at http://sitem.herts.ac.uk/aeru/ppdb/en [verified 25 April 2019]
Ramos AM, Whelan MJ, Cosgrove S, Villa R, Jefferson B, Campo P, Jarvis P, Guymer I (2017). A multi-residue method to determine pesticides in surface water by liquid chromatography–tandem quadrupole mass spectrometry. Water and Environment Journal 31, 380–387.
| A multi-residue method to determine pesticides in surface water by liquid chromatography–tandem quadrupole mass spectrometryCrossref | GoogleScholarGoogle Scholar |
Rocha F, Walker A (1995). Simulation of the persistence of atrazine in soil at different sites in Portugal. Weed Research 35, 179–186.
| Simulation of the persistence of atrazine in soil at different sites in PortugalCrossref | GoogleScholarGoogle Scholar |
Rolph C, Jefferson B, Hassard F, Villa R (2018). Metaldehyde removal from drinking water by adsorption onto filtration media: mechanisms and optimisation. Environmental Science. Water Research & Technology 4, 1543–1552.
| Metaldehyde removal from drinking water by adsorption onto filtration media: mechanisms and optimisationCrossref | GoogleScholarGoogle Scholar |
Scholz M, Harrington R, Carroll P, Mustafa A (2007). The Integrated Constructed Wetlands (ICW) concept. Wetlands 27, 337–354.
| The Integrated Constructed Wetlands (ICW) conceptCrossref | GoogleScholarGoogle Scholar |
Schulz R, Peall SKC (2001). Effectiveness of a constructed wetland for retention of non-point-source pesticide pollution in the Lourens River catchment, South Africa. Environmental Science & Technology 35, 422–426.
| Effectiveness of a constructed wetland for retention of non-point-source pesticide pollution in the Lourens River catchment, South AfricaCrossref | GoogleScholarGoogle Scholar |
Seitzinger SP, Styles RV, Boyer EW, Alexander RB, Billen G, Howarth RW, Mayer B, van Breemen N (2002). Nitrogen retention in rivers: model development and application to watersheds in the north-eastern USA. Biogeochemistry 57, 199–237.
| Nitrogen retention in rivers: model development and application to watersheds in the north-eastern USACrossref | GoogleScholarGoogle Scholar |
Sonnenwald F, Stovin V, Guymer I (2015). Deconvolving smooth residence time distributions from raw solute transport data. Journal of Hydrologic Engineering 20, 04015022
| Deconvolving smooth residence time distributions from raw solute transport dataCrossref | GoogleScholarGoogle Scholar |
Sonnenwald F, Hart JR, West P, Stovin VR, Guymer I (2017). Transverse and longitudinal mixing in real emergent vegetation at low velocities. Water Resources Research 53,
| Transverse and longitudinal mixing in real emergent vegetation at low velocitiesCrossref | GoogleScholarGoogle Scholar |
Stovin VR, Guymer I, Chappell MJ, Hattersley JG (2010). The use of deconvolution techniques to identify the fundamental mixing characteristics of urban drainage structures. Water Science and Technology 61, 2075–2081.
| The use of deconvolution techniques to identify the fundamental mixing characteristics of urban drainage structuresCrossref | GoogleScholarGoogle Scholar | 20389006PubMed |
Tediosi A, Whelan MJ, Rushton KR, Thompson TRE, Gandolfi C, Pullan SP (2012). Measurement and conceptual modelling of herbicide transport to field drains in a heavy clay soil with implications for catchment-scale water quality management. The Science of the Total Environment 438, 103–112.
| Measurement and conceptual modelling of herbicide transport to field drains in a heavy clay soil with implications for catchment-scale water quality managementCrossref | GoogleScholarGoogle Scholar | 22982449PubMed |
Tediosi A, Whelan MJ, Rushton KR, Gandolfi C (2013). Predicting rapid herbicide leaching to surface waters from an artificially drained headwater catchment using a one dimensional two-domain model coupled with a simple groundwater model. Journal of Contaminant Hydrology 145, 67–81.
| Predicting rapid herbicide leaching to surface waters from an artificially drained headwater catchment using a one dimensional two-domain model coupled with a simple groundwater modelCrossref | GoogleScholarGoogle Scholar | 23313906PubMed |
Whelan MJ, Gandolfi C, Bischetti GB (1999). A simple stochastic model of point source solute transport in rivers based on gauging station data with implications for sampling requirements. Water Research 33, 3171–3181.
| A simple stochastic model of point source solute transport in rivers based on gauging station data with implications for sampling requirementsCrossref | GoogleScholarGoogle Scholar |
Whelan MJ, van Egmond R, Guymer I, Lacoursiere JO, Vought LMB, Finnegan C, Fox KK, Sparham C, O’Connor S, Vaughan M, Pearson JM (2007). The behaviour of linear alkyl benzene sulphonate under direct discharge conditions in Vientiane, Lao PDR. Water Research 41, 4730–4740.
| The behaviour of linear alkyl benzene sulphonate under direct discharge conditions in Vientiane, Lao PDRCrossref | GoogleScholarGoogle Scholar | 17658579PubMed |
Whelan MJ, Coulon F, Hince G, Rayner J, McWatters R, Spedding T, Snape I (2015). Fate and transport of petroleum hydrocarbons in engineered biopiles in polar regions. Chemosphere 131, 232–240.
| Fate and transport of petroleum hydrocarbons in engineered biopiles in polar regionsCrossref | GoogleScholarGoogle Scholar | 25563162PubMed |