30 research outputs found
Quantifying pelagic phosphorus regeneration using three methods in lakes of varying productivity
Phosphorus (P) is often a limiting nutrient in freshwater ecosystems, and understanding P dynamics in lakes is critical for eutrophication management. Pelagic P regeneration can support a large fraction of primary production in stratified freshwaters. Various techniques have been used to quantify pelagic P regeneration including (1) P mass balance supply–demand, (2) regression using total P as a predictor, and, more recently, (3) whole-lake metabolism calculated from high-frequency dissolved oxygen (DO) data. To our knowledge no study comparing these methods in multiple lakes has been performed. To compare these 3 approaches, we investigated 3 Global Lake Ecological Observatory Network (GLEON) lakes that differ in productivity: Acton, a Midwestern USA hypereutrophic reservoir; and 2 Northeastern USA glacial lakes, oligotrophic Giles and mesotrophic/dystrophic Lacawac. In Acton, we used all 3 methods, but for Giles and Lacawac we used only the total P regression and metabolism techniques. Our results show the best agreement among methods in the mesotrophic lake, whereas the metabolism approach underestimated regeneration in the oligotrophic lake and overestimated regeneration in the hypereutrophic reservoir compared with other methods. P regeneration rates for the hypereutrophic reservoir were the most sensitive to the metabolism-based input parameters. Our study illustrates a novel use of high-frequency DO data, which are commonly collected on many GLEON buoys, to understand lake nutrient dynamics
Increased winter drownings in ice-covered regions with warmer winters
Winter activities on ice are culturally important for many countries, yet they constitute a high
safety risk depending upon the stability of the ice. Because consistently cold periods are
required to form stable and thick ice, warmer winters could degrade ice conditions and
increase the likelihood of falling through the ice. This study provides the first large-scale
assessment of winter drowning from 10 Northern Hemisphere countries. We documented
over 4000 winter drowning events. Winter drownings increased exponentially in regions with
warmer winters when air temperatures neared 0 ĚŠC. The largest number of drownings
occurred when winter air temperatures were between -5 ĚŠC and 0 ĚŠC, when ice is less stable,
and also in regions where indigenous traditions and livelihood require extended time on ice.
Rates of drowning were greatest late in the winter season when ice stability declines. Children and adults up to the age of 39 were at the highest risk of winter drownings. Beyond temperature, differences in cultures, regulations, and human behaviours can be important
additional risk factors. Our findings indicate the potential for increased human mortality with
warmer winter air temperatures. Incorporating drowning prevention plans would improve
adaptation strategies to a changing climate.Funding was provided to SS by the
Ontario Ministry of Research, Innovation and
Science Early Researcher Award and York
University Research Chair programme. Funding
support for BAD was provided by
Kempestiftelserna. AL was supported by Estonian
Research Council Grant PSG 32. The funders had
no role in study design, data collection and analysis, decision to publish, or preparation of the
manuscript.Funding was provided to SS by the
Ontario Ministry of Research, Innovation and
Science Early Researcher Award and York
University Research Chair programme. Funding
support for BAD was provided by
Kempestiftelserna. AL was supported by Estonian
Research Council Grant PSG 32. The funders had
no role in study design, data collection and analysis, decision to publish, or preparation of the
manuscript
The potential of high-frequency profiling to assess vertical and seasonal patterns of phytoplankton dynamics in lakes: An extension of the Plankton Ecology Group (PEG) model
The use of high-frequency sensors on profiling buoys to investigate physical, chemical, and biological processes in lakes is increasing rapidly. Profiling buoys with automated winches and sensors that collect high-frequency chlorophyll fluorescence (ChlF) profiles in 11 lakes in the Global Lake Ecological Observatory Network (GLEON) allowed the study of the vertical and temporal distribution of ChlF, including the formation of subsurface chlorophyll maxima (SSCM). The effectiveness of 3 methods for sampling phytoplankton distributions in lakes, including (1) manual profiles, (2) single-depth buoys, and (3) profiling buoys were assessed. High-frequency ChlF surface data and profiles were compared to predictions from the Plankton Ecology Group (PEG) model. The depth-integrated ChlF dynamics measured by the profiling buoy data revealed a greater complexity that neither conventional sampling nor the generalized PEG model captured. Conventional sampling techniques would have missed SSCM in 7 of 11 study lakes. Although surface-only ChlF data underestimated average water column ChlF, at times by nearly 2-fold in 4 of the lakes, overall there was a remarkable similarity between surface and mean water column data. Contrary to the PEG model’s proposed negligible role for physical control of phytoplankton during the growing season, thermal structure and light availability were closely associated with ChlF seasonal depth distribution. Thus, an extension of the PEG model is proposed, with a new conceptual framework that explicitly includes physical metrics to better predict SSCM formation in lakes and highlight when profiling buoys are especially informative
Climate change drives widespread shifts in lake thermal habitat
Lake surfaces are warming worldwide, raising concerns about lake organism responses to thermal habitat changes. Species may cope with temperature increases by shifting their seasonality or their depth to track suitable thermal habitats, but these responses may be constrained by ecological interactions, life histories or limiting resources. Here we use 32 million temperature measurements from 139 lakes to quantify thermal habitat change (percentage of non-overlap) and assess how this change is exacerbated by potential habitat constraints. Long-term temperature change resulted in an average 6.2% non-overlap between thermal habitats in baseline (1978–1995) and recent (1996–2013) time periods, with non-overlap increasing to 19.4% on average when habitats were restricted by season and depth. Tropical lakes exhibited substantially higher thermal non-overlap compared with lakes at other latitudes. Lakes with high thermal habitat change coincided with those having numerous endemic species, suggesting that conservation actions should consider thermal habitat change to preserve lake biodiversity
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Widespread deoxygenation of temperate lakes
The concentration of dissolved oxygen in aquatic systems helps to regulate biodiversity, nutrient biogeochemistry, greenhouse gas emissions, and the quality of drinking water. The long-term declines in dissolved oxygen concentrations in coastal and ocean waters have been linked to climate warming and human activity, but little is known about the changes in dissolved oxygen concentrations in lakes. Although the solubility of dissolved oxygen decreases with increasing water temperatures, long-term lake trajectories are difficult to predict. Oxygen losses in warming lakes may be amplified by enhanced decomposition and stronger thermal stratification8,9 or oxygen may increase as a result of enhanced primary production. Here we analyse a combined total of 45,148 dissolved oxygen and temperature profiles and calculate trends for 393 temperate lakes that span 1941 to 2017. We find that a decline in dissolved oxygen is widespread in surface and deep-water habitats. The decline in surface waters is primarily associated with reduced solubility under warmer water temperatures, although dissolved oxygen in surface waters increased in a subset of highly productive warming lakes, probably owing to increasing production of phytoplankton. By contrast, the decline in deep waters is associated with stronger thermal stratification and loss of water clarity, but not with changes in gas solubility. Our results suggest that climate change and declining water clarity have altered the physical and chemical environment of lakes. Declines in dissolved oxygen in freshwater are 2.75 to 9.3 times greater than observed in the world’s oceans and could threaten essential lake ecosystem services
Global data set of long-term summertime vertical temperature profiles in 153 lakes
Climate change and other anthropogenic stressors have led to long-term changes in the thermal structure, including surface temperatures, deepwater temperatures, and vertical thermal gradients, in many lakes around the world. Though many studies highlight warming of surface water temperatures in lakes worldwide, less is known about long-term trends in full vertical thermal structure and deepwater temperatures, which have been changing less consistently in both direction and magnitude. Here, we present a globally-expansive data set of summertime in-situ vertical temperature profiles from 153 lakes, with one time series beginning as early as 1894. We also compiled lake geographic, morphometric, and water quality variables that can influence vertical thermal structure through a variety of potential mechanisms in these lakes. These long-term time series of vertical temperature profiles and corresponding lake characteristics serve as valuable data to help understand changes and drivers of lake thermal structure in a time of rapid global and ecological change
Global data set of long-term summertime vertical temperature profiles in 153 lakes
Measurement(s) : temperature of water, temperature profile
Technology Type(s) : digital curation
Factor Type(s) : lake location, temporal interval
Sample Characteristic - Environment : lake, reservoir
Sample Characteristic - Location : global
Machine-accessible metadata file describing the reported data: https://doi.org/10.6084/m9.figshare.14619009Climate change and other anthropogenic stressors have led to long-term changes in the thermal structure, including surface temperatures, deepwater temperatures, and vertical thermal gradients, in many lakes around the world. Though many studies highlight warming of surface water temperatures in lakes worldwide, less is known about long-term trends in full vertical thermal structure and deepwater temperatures, which have been changing less consistently in both direction and magnitude. Here, we present a globally-expansive data set of summertime in-situ vertical temperature profiles from 153 lakes, with one time series beginning as early as 1894. We also compiled lake geographic, morphometric, and water quality variables that can influence vertical thermal structure through a variety of potential mechanisms in these lakes. These long-term time series of vertical temperature profiles and corresponding lake characteristics serve as valuable data to help understand changes and drivers of lake thermal structure in a time of rapid global and ecological change
Trends in Temperature and Dissolved Oxygen in Midwestern Urban Lakes
National Conference on Undergraduate ResearchUrban lakes provide many ecosystem services, but urban
development threatens the health of aquatic habitats. Fertilizers from
lawns and golf courses run-off and excess nutrients favor harmful
algal blooms ultimately depleting dissolved oxygen (DO). Urban
areas also experience the Urban Heat Island effect, whereby
increased infrastructure and decreased albedo lead to warmer
temperatures (Yang et al., 2016; Figure 1).
In temperate regions, such as the Upper Midwest, lakes stratify in
the summer. The upper layer (epilimnion) is warm and supports
primary production while the cooler bottom layer (hypolimnion) is a
summer refuge for fish in undisturbed lakes (Figure 2).
Decadal length or longer datasets are needed to identify the effects
of slow processes such as urbanization. Changes in lake
temperature are confounded by stratification; hypolimnion
temperature may respond differently than the epilimnion.
The Twin Cities (MN) have grown rapidly in recent decades and have
many lakes in their metro area (Figures 1, 3). As a result, these lakes
are an excellent target for investigating the relationship between
urbanization and long-term trends in DO and temperature.Office of Research & Sponsored Program