Hydrology Research (Apr 2022)

Green infrastructure and climate change impacts on the flows and water quality of urban catchments: Salmons Brook and Pymmes Brook in north-east London

  • Gianbattista Bussi,
  • Paul G. Whitehead,
  • Rosie Nelson,
  • John Bryden,
  • Christopher R. Jackson,
  • Andrew G. Hughes,
  • Adrian P. Butler,
  • Catharina Landström,
  • Helge Peters,
  • Simon Dadson,
  • Ian Russell

DOI
https://doi.org/10.2166/nh.2022.013
Journal volume & issue
Vol. 53, no. 4
pp. 638 – 656

Abstract

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Poor water quality is a widespread issue in urban rivers and streams in London. Localised pollution can have impacts on local communities, from health issues to environmental degradation and restricted recreational use of water. The Salmons and Pymmes Brooks, located in the London Borough of Enfield, flow into the River Lee, and in this paper, the impacts of misconnected sewers, urban runoff and atmospheric pollution have been evaluated. The first step towards finding a sustainable and effective solution to these issues is to identify sources and paths of pollutants and to understand their cycle through catchments and rivers. The INCA water quality model has been applied to the Salmons and Pymmes urban catchments in north-east London, with the aim of providing local communities and community action groups such as Thames21 with a tool they can use to assess the water quality issue. INCA is a process-based, dynamic flow and quality model, and so it can account for daily changes in temperature, flow, water velocity and residence time that all affect reaction kinetics and hence chemical flux. As INCA is process-based, a set of mitigation strategies have been evaluated including constructed wetland across the catchment to assess pollution control. The constructed wetlands can make a significant difference reducing sediment transport and improving nutrient control for nitrogen and phosphorus. The results of this paper show that a substantial reduction in nitrate, ammonium and phosphorus concentrations can be achieved if a proper catchment-scale wetland implementation strategy is put in place. Furthermore, the paper shows how the nutrient reduction efficiency of the wetlands should not be affected by climate change. HIGHLIGHTS Modelling urban flows and water quality in London streams is demonstrated.; Impacts of pollution, deposition and urban runoff are illustrated under future climate change.; The paper uses a dynamic process-based water quality model to assess impacts of wetlands.; Constructed wetlands can make a significant difference improving nutrient control.; Mitigation measures significantly reduce nitrate, ammonium and phosphorus.;

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