2019
DOI: 10.1029/2019wr025019
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On the Role of a Large Shallow Lake (Lake St. Clair, USA‐Canada) in Modulating Phosphorus Loads to Lake Erie

Abstract: It is often assumed that large shallow water bodies are net sediment nondepositional annually and that if they have nutrient loads from multiple sources, those loads are quickly homogenized before exiting the water bodies. Where this is not the case, it impacts understanding and predicting consequences of nutrient load reductions, both for the water body and for those downstream of it. We applied a threedimensional ecological model to a large shallow lake, Lake St. Clair (US/Canada), to quantify the total and … Show more

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Cited by 10 publications
(8 citation statements)
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“…The simulated effects of altered air temperature and wind speed were largely as expected, with warmer temperatures and weaker winds exacerbating hypoxia and anoxia. The results supported previous findings that variations of climatic air temperature are of comparable importance to changes in nutrient loads (Bocaniov et al, 2016, 2017, 2019; Bocaniov & Scavia, 2016; Del Giudice et al, 2018). The model outcomes give the first evidence that changes in ice cover are an important state change that will likely amplify the otherwise linear and proportional response of hypoxia to air temperature over the expected range of 21st century values.…”
Section: Discussionsupporting
confidence: 91%
“…The simulated effects of altered air temperature and wind speed were largely as expected, with warmer temperatures and weaker winds exacerbating hypoxia and anoxia. The results supported previous findings that variations of climatic air temperature are of comparable importance to changes in nutrient loads (Bocaniov et al, 2016, 2017, 2019; Bocaniov & Scavia, 2016; Del Giudice et al, 2018). The model outcomes give the first evidence that changes in ice cover are an important state change that will likely amplify the otherwise linear and proportional response of hypoxia to air temperature over the expected range of 21st century values.…”
Section: Discussionsupporting
confidence: 91%
“…Amongst all tributaries discharging into Lake Erie, the Thames River ranks 3 rd behind the Maumee and Sandusky Rivers in contributing TP and SRP to Lake Erie ( Maccoux et al, 2016 ; Figure 1 ). Although the largest annual hydrological loads to Lake St. Clair come from the St. Clair River (average 2016–2019 discharge of 6,122 m 3 /s), which flows directly from Lake Huron, the Thames River has a disproportionate effect on the TP load, to the extent that P reduction in the Thames River basin will be more effective in reducing the P export from Lake St. Clair than from the equivalent in-flow Sydenham or Clinton Rivers ( Bocaniov et al, 2019 ). Lake St. Clair has a water residence time of ~9 days, and due to it shallow depth, is subjected to frequent vertical mixing, yet nutrient loads from its tributaries are not homogeneously mixed and vary seasonally and spatially ( Bocaniov et al, 2019 ).…”
Section: Discussionmentioning
confidence: 99%
“…Although the largest annual hydrological loads to Lake St. Clair come from the St. Clair River (average 2016–2019 discharge of 6,122 m 3 /s), which flows directly from Lake Huron, the Thames River has a disproportionate effect on the TP load, to the extent that P reduction in the Thames River basin will be more effective in reducing the P export from Lake St. Clair than from the equivalent in-flow Sydenham or Clinton Rivers ( Bocaniov et al, 2019 ). Lake St. Clair has a water residence time of ~9 days, and due to it shallow depth, is subjected to frequent vertical mixing, yet nutrient loads from its tributaries are not homogeneously mixed and vary seasonally and spatially ( Bocaniov et al, 2019 ). Lake St. Clair has also been shown to be a sink for nutrients retaining up to 20% of the TP load ( Bocaniov et al, 2019 ; Scavia et al, 2019 ), but altogether with loads from Canada and the US still contributes up to 41% of the annual TP load to Lake Erie’s Western Basin via the Detroit River (average 2016–2019 discharge of 6,383 m 3 /s), which is the second in importance after the Maumee River which contributes up to 48% ( Scavia et al, 2016 ).…”
Section: Discussionmentioning
confidence: 99%
“…[ 18 ], as well as habitat variation [ 14 ], among sampling locations, are strong drivers of the spatial variation of the microbial communities. We did not measure abiotic parameters such as nutrient levels at our sampling locations; however, due to the connectivity of the two lakes by the Detroit River [ 19 ], the short distances among the sampling locations and the eutrophication of Lake Erie [ 5 ] and St. Clair [ 20 ], our sampling locations might have similar habitat features which consequently resulted in the little spatial variation of the BCCs in our study. The chao 1 index of CB was higher than other sampling sites, potentially due to presence of more greenhouse agriculture area and consequently higher bioavailability of nutrients; however, more studies are needed to address the influence of greenhouse agriculture area on BC diversity.…”
Section: Discussionmentioning
confidence: 99%