Coupling Water Column and Sediment Biogeochemical Dynamics: Modeling Internal Phosphorus Loading, Climate Change Responses, and Mitigation Measures in Lake Vansjø, Norway

Markelov, Igor; Couture, Raoul-Marie; Fischer, Rachele; Haande, Sigrid; Cappellen, Philippe Van

doi:10.1029/2019jg005254

Cited by 36 publications

(24 citation statements)

References 119 publications

(185 reference statements)

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“…Nitrogen processing models such as Global NEWS (Mayorga et al., 2010) and nutrient loading models such as PCLake+ (Janssen et al., 2019) and VEMALA (Huttunen et al., 2016), often include denitrification as a nitrogen conversion term. Moreover, other ecosystem models such as the MyLake‐Sediment model (Markelov et al., 2019) and the terrestrial NEMIS model (Hénault & Germon, 2000), even use (derivatives of) Q10‐values to describe the temperature sensitivity of denitrification. Our meta‐analytic results provide an overview of in‐situ Q10‐values for a wide range of ecosystems (Table S1 in Supporting Information S1), which can potentially aid the modeling of the temperature sensitivity of denitrification for specific freshwater ecosystems.…”

Section: Discussionmentioning

confidence: 99%

Temperature Sensitivity of Freshwater Denitrification and N₂O Emission—A Meta‐Analysis

Velthuis

Veraart

2022

Global Biogeochemical Cycles

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Freshwater denitrification removes a considerable amount of nitrogen from inland waters, which are under pressure from eutrophication and warming. However, incomplete denitrification can lead to the formation of N2O, a potent greenhouse gas, which can amplify climatic warming. Although temperature effects on denitrification are well studied in individual habitats and experiments, global patterns in temperature‐responses of denitrification and N2O emissions remain to be elucidated. Here, we investigated the temperature sensitivity (Q10) of denitrification and N2O emissions in freshwater ecosystems worldwide, using a meta‐analytic approach. To this end, Q10 values from in‐situ and temperature manipulation studies were related to environmental nutrient conditions, O2, pH, sediment organic matter (SOM), and geographic location. Temperature sensitivity of denitrification displayed a strong positive correlation with environmental nitrogen concentrations, pH and O2. Significant correlations with SOM and SOM:N ratios were observed as well, but the direction of the effect differed between in‐situ and temperature manipulation studies. Surprisingly, temperature sensitivity of N2O emissions did not correlate with pH, SOM, nutrient or O2 conditions. Temperature sensitivity of the ratio between N2O emission and NO3− concentration (adapted EF5 values) was 6.6 times higher in Australia and New Zealand compared to other geographic regions. As global temperatures and nitrogen deposition in freshwater ecosystems are expected to increase over the coming decades, our results suggest enhanced future denitrification, which may present a natural way to balance eutrophication. The observed temperature sensitivity of N2O emission factors, however, may indicate enhanced denitrification‐derived N2O emissions from freshwater ecosystems in a future warmer world.

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Section: Discussionmentioning

confidence: 99%

Temperature Sensitivity of Freshwater Denitrification and N₂O Emission—A Meta‐Analysis

Velthuis

Veraart

2022

Global Biogeochemical Cycles

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“…Aim 2: Lake modeling MyLake is a 1D process-oriented model designed to simulate seasonal ice and snow cover, heat exchange and thermal stratification, N and P cycling, phytoplankton growth, oxygen and carbon dynamics, and water-sediment coupling (Saloranta and Andersen 2007;Couture et al 2015;de Wit et al 2018;Kiuru et al 2019;Markelov et al 2019). The model has previously been applied to boreal lakes to simulate the response of P cycling to external P loading and climate change (Couture et al 2014a(Couture et al , 2018.…”

Section: Study Site and Aim 1: Historical Trendsmentioning

confidence: 99%

Warming combined with experimental eutrophication intensifies lake phytoplankton blooms

Salk

Venkiteswaran

Couture

et al. 2021

Limnology & Oceanography

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Phytoplankton blooms are a global water quality issue, and successful management depends on understanding their responses to multiple and interacting drivers, including nutrient loading and climate change. Here, we examine a long-term dataset from Lake 227, a site subject to a fertilization experiment (1969-present) with changing nitrogen:phosphorus (N:P) ratios. We applied a process-oriented model, MyLake, and updated the model structure with nutrient uptake kinetics that incorporated shifting N:P and competition among phytoplankton functional groups. We also tested different temperature and P-loading scenarios to examine the interacting effects of climate change and nutrient loading on phytoplankton blooms. The model successfully reproduced lake physics over 48 yr and the timing, overall magnitude, and shifting community structure (diazotrophs vs. non-diazotrophs) of phytoplankton blooms. Intra-and interannual variability was captured more accurately for the P-only fertilization period than for the high N:P and low N:P fertilization periods, highlighting the difficulty of modeling complex blooms even in well-studied systems. A model scenario was also run which removed climate-driven temperature trends, allowing us to disentangle concurrent drivers of blooms. Results showed that increases in water temperature in the spring led to earlier and larger phytoplankton blooms under climate change than under the effects of nutrient fertilization alone. These findings suggest that successful lake management efforts should incorporate the effects of climate change in addition to nutrient reductions, including intensifying and/or expanding monitoring periods and incorporating climate change into uncertainty estimates around future conditions.

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“…For the purpose of planning lake restoration, accounting for hydrodynamics, ecosystem functioning and sediment processes may be necessary (Trolle et al, 2011;Smits & van Beek, 2013;Hipsey et al, 2015;Zhang et al, 2015;Hu et al, 2016). Recently, the coupling of stateof-the-art lake models (Hipsey et al, 2020;Rousso et al, 2020) with sediment diagenetic models (e.g., Gudimov et al, 2016;Matisoff et al, 2016;Doan et al, 2018) has been promoted specifically to address gaps in lake resaturation planning (Markelov et al, 2019;Messina et al, 2020). A key future perspective is thus the improved integration of the required modeling infrastructure to test different restoration scenarios.…”

Section: Future Perspectivesmentioning

confidence: 99%

Preface: Restoration of eutrophic lakes: current practices and future challenges

et al. 2020

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Coupling Water Column and Sediment Biogeochemical Dynamics: Modeling Internal Phosphorus Loading, Climate Change Responses, and Mitigation Measures in Lake Vansjø, Norway

Cited by 36 publications

References 119 publications

Temperature Sensitivity of Freshwater Denitrification and N₂O Emission—A Meta‐Analysis

Temperature Sensitivity of Freshwater Denitrification and N₂O Emission—A Meta‐Analysis

Warming combined with experimental eutrophication intensifies lake phytoplankton blooms

Preface: Restoration of eutrophic lakes: current practices and future challenges

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Coupling Water Column and Sediment Biogeochemical Dynamics: Modeling Internal Phosphorus Loading, Climate Change Responses, and Mitigation Measures in Lake Vansjø, Norway

Cited by 36 publications

References 119 publications

Temperature Sensitivity of Freshwater Denitrification and N2O Emission—A Meta‐Analysis

Temperature Sensitivity of Freshwater Denitrification and N2O Emission—A Meta‐Analysis

Warming combined with experimental eutrophication intensifies lake phytoplankton blooms

Preface: Restoration of eutrophic lakes: current practices and future challenges

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Product

Resources

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Temperature Sensitivity of Freshwater Denitrification and N₂O Emission—A Meta‐Analysis

Temperature Sensitivity of Freshwater Denitrification and N₂O Emission—A Meta‐Analysis