A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)

A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)

Process-based models are commonly used to design management strategies to reduce excessive algal growth and subsequent hypoxia. However, management targets typically focus on phosphorus control, under the assumption that successful nutrient reduction will solve hypoxia issues. Algal responses to nut...

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Main Authors: Jill Crossman, Gianbattista Bussi, Paul G. Whitehead, Daniel Butterfield, Emma Lannergård, Martyn N. Futter
Format: Article
Language:English
Published: MDPI AG 2021-03-01
Series:Water
Subjects:
phytoplankton
dissolved oxygen
biological oxygen demand
modelling
sensitivity analysis
Online Access:https://www.mdpi.com/2073-4441/13/5/723
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spelling doaj-ab143b4d49db44eeb4f23fd424cb3c692021-03-08T00:00:11ZengMDPI AGWater2073-44412021-03-011372372310.3390/w13050723A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)Jill Crossman0Gianbattista Bussi1Paul G. Whitehead2Daniel Butterfield3Emma Lannergård4Martyn N. Futter5School of the Environment, University of Windsor, Windsor, ON N9B 3P4, CanadaSchool of Geography and the Environment, University of Oxford, Oxford OX1 3QY, UKSchool of Geography and the Environment, University of Oxford, Oxford OX1 3QY, UKEnmosys, VT, USADepartment of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE 750 07 Uppsala, SwedenDepartment of Aquatic Sciences and Assessment, Swedish University of Agricultural Sciences, SE 750 07 Uppsala, SwedenProcess-based models are commonly used to design management strategies to reduce excessive algal growth and subsequent hypoxia. However, management targets typically focus on phosphorus control, under the assumption that successful nutrient reduction will solve hypoxia issues. Algal responses to nutrient drivers are not linear and depend on additional biotic and abiotic controls. In order to generate a comprehensive assessment of the effectiveness of nutrient control strategies, independent nutrient, dissolved oxygen (DO), temperature and algal models must be coupled, which can increase overall uncertainty. Here, we extend an existing process-based phosphorus model (INtegrated CAtchment model of Phosphorus dynamics) to include biological oxygen demand (BOD), dissolved oxygen (DO) and algal growth and decay (INCA-PEco). We applied the resultant model in two eutrophied mesoscale catchments with continental and maritime climates. We assessed effects of regional differences in climate and land use on parameter importance during calibration using a generalised sensitivity analysis. We successfully reproduced in-stream total phosphorus (TP), suspended sediment, DO, BOD and chlorophyll-a (chl-a) concentrations across a range of temporal scales, land uses and climate regimes. While INCA-PEco is highly parameterized, model uncertainty can be significantly reduced by focusing calibration and monitoring efforts on just 18 of those parameters. Specifically, calibration time could be optimized by focusing on hydrological parameters (base flow, Manning’s n and river depth). In locations with significant inputs of diffuse nutrients, e.g., in agricultural catchments, detailed data on crop growth and nutrient uptake rates are also important. The remaining parameters provide flexibility to the user, broaden model applicability, and maximize its functionality under a changing climate.https://www.mdpi.com/2073-4441/13/5/723phytoplanktondissolved oxygenbiological oxygen demandmodellingsensitivity analysis
collection DOAJ
language English
format Article
sources DOAJ
author Jill Crossman
Gianbattista Bussi
Paul G. Whitehead
Daniel Butterfield
Emma Lannergård
Martyn N. Futter
spellingShingle Jill Crossman
Gianbattista Bussi
Paul G. Whitehead
Daniel Butterfield
Emma Lannergård
Martyn N. Futter
A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)
Water
phytoplankton
dissolved oxygen
biological oxygen demand
modelling
sensitivity analysis
author_facet Jill Crossman
Gianbattista Bussi
Paul G. Whitehead
Daniel Butterfield
Emma Lannergård
Martyn N. Futter
author_sort Jill Crossman
title A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)
title_short A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)
title_full A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)
title_fullStr A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)
title_full_unstemmed A New, Catchment-Scale Integrated Water Quality Model of Phosphorus, Dissolved Oxygen, Biochemical Oxygen Demand and Phytoplankton: INCA-Phosphorus Ecology (PEco)
title_sort new, catchment-scale integrated water quality model of phosphorus, dissolved oxygen, biochemical oxygen demand and phytoplankton: inca-phosphorus ecology (peco)
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2021-03-01
description Process-based models are commonly used to design management strategies to reduce excessive algal growth and subsequent hypoxia. However, management targets typically focus on phosphorus control, under the assumption that successful nutrient reduction will solve hypoxia issues. Algal responses to nutrient drivers are not linear and depend on additional biotic and abiotic controls. In order to generate a comprehensive assessment of the effectiveness of nutrient control strategies, independent nutrient, dissolved oxygen (DO), temperature and algal models must be coupled, which can increase overall uncertainty. Here, we extend an existing process-based phosphorus model (INtegrated CAtchment model of Phosphorus dynamics) to include biological oxygen demand (BOD), dissolved oxygen (DO) and algal growth and decay (INCA-PEco). We applied the resultant model in two eutrophied mesoscale catchments with continental and maritime climates. We assessed effects of regional differences in climate and land use on parameter importance during calibration using a generalised sensitivity analysis. We successfully reproduced in-stream total phosphorus (TP), suspended sediment, DO, BOD and chlorophyll-a (chl-a) concentrations across a range of temporal scales, land uses and climate regimes. While INCA-PEco is highly parameterized, model uncertainty can be significantly reduced by focusing calibration and monitoring efforts on just 18 of those parameters. Specifically, calibration time could be optimized by focusing on hydrological parameters (base flow, Manning’s n and river depth). In locations with significant inputs of diffuse nutrients, e.g., in agricultural catchments, detailed data on crop growth and nutrient uptake rates are also important. The remaining parameters provide flexibility to the user, broaden model applicability, and maximize its functionality under a changing climate.
topic phytoplankton
dissolved oxygen
biological oxygen demand
modelling
sensitivity analysis
url https://www.mdpi.com/2073-4441/13/5/723
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