Dissolved oxygen dynamics under ice: Three winters of high‐frequency data from <scp>L</scp>ake <scp>T</scp>ovel, <scp>I</scp>taly

Obertegger, Ulrike; Obrador, Biel; Flaim, Giovanna

doi:10.1002/2017wr020599

Cited by 43 publications

(50 citation statements)

References 60 publications

(106 reference statements)

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“…Thus, although irradiance decreased rapidly in the water column and PAR values at the bottom varied between 0 and 5 W/m 2 (unpublished data), even such a low level of PAR seemed to be high enough for photosynthesis to occur. Our observations are in accordance with Obertegger, Obrador, and Flaim () who analysed under‐ice DO dynamics in an oligotrophic lake, and with Hanke et al. () who studied phytoplankton growth and photosynthesis under thick snow and sea‐ice in Greenland.…”

Section: Discussionsupporting

confidence: 93%

Under‐ice metabolism in a shallow lake in a cold and arid climate

Song

Shi

et al. 2019

Freshwater Biology

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Winter is a long period of the annual cycle of many lakes in the northern hemisphere. Low irradiance, ice, and snow cover cause poor light penetration into the water column of these lakes. Therefore, in northern lakes, respiration often exceeds primary production leading to low dissolved oxygen concentrations. This study aimed to quantify under‐ice metabolic processes during winter in an arid zone lake with little snow cover. This study was carried out in a mid‐latitude lake in Inner Mongolia, northern China. The study lake receives relatively high incoming solar radiation on the ice in mid‐winter, and radiation can penetrate down to the bottom sediment as the lake is shallow and the ice lacks snow cover. Primary production and respiration were estimated during two winters using high‐frequency sensor measurements of dissolved oxygen. To quantify under‐ice metabolic processes, sensors were deployed to different depths. During both winters, sensors collected data every 10 min over several weeks. The amount of solar radiation controlled photosynthesis under ice; temperature and photosynthesis together appeared to control respiration. The balance between gross primary production and ecosystem respiration was especially sensitive to changes in snow cover, and the balance between P and R decreased. Our data suggest that photosynthesis by plankton, submerged plants, and epiphytic algae may continue over winter in shallow lakes in mid‐latitudes when there is no snow cover on the ice, as may occur in arid climates. The continuation of photosynthesis under ice buffers against dissolved oxygen depletion and prevents consequent harmful ecosystem effects.

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Section: Discussionsupporting

confidence: 93%

Under‐ice metabolism in a shallow lake in a cold and arid climate

Song

Shi

et al. 2019

Freshwater Biology

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“…In addition to water temperature, climate change also influences other important physical and biological state variables of temperate lakes, such as ice phenology, dissolved oxygen (DO), and chlorophyll a (Couture et al, ; Fang & Stefan, ; Kraemer et al, ). These variables regulate important biogeochemical processes (e.g., carbon burial and degradation) in both water and sediment columns (Evans et al, ; Ferland et al, ; Istvánovics & Honti, ; Müller et al, ; Obertegger et al, ) and are indicators of water quality (Dillon et al, ; Jiang et al, ). For instance, important cold‐water fish such as salmon and brown trout thrive in a habitat of combining high DO concentrations and low water temperature (Dillon et al, ; Jiang et al, ), typical for the hypolimnion of natural temperate oligotrophic lakes.…”

Section: Introductionmentioning

confidence: 99%

“…To date, our understanding of the future dynamics of these state variables in small temperate lakes is still limited (Couture et al, ; Fang & Stefan, ; Obertegger et al, ; Oliver et al, ; Yao et al, ). First, although the processes that control the dynamics of water temperature, ice phenology, DO, and chlorophyll a are closely interacted (Couture et al, ; Giling et al, ; Obertegger et al, ), the modeling studies for small temperate lakes usually only focused on one or two of these variables (Vincent et al, ; Yao et al, ) and few modeling studies have predicted the chlorophyll a dynamics (Fang & Stefan, ; Joehnk & Umlauf, ; Yao et al, ). Second, the difference of DO dynamics in surface and deep waters was less explored and the impacts of catchments on the future changes of lakes were sometimes ignored (Fang & Stefan, ).…”

Section: Introductionmentioning

confidence: 99%

A Small Temperate Lake in the 21st Century: Dynamics of Water Temperature, Ice Phenology, Dissolved Oxygen, and Chlorophyll a

Tan

Yao

Zhuang

2018

Water Resources Research

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It is unclear how small temperate lakes will evolve physically and biologically in the whole water column under future climate because previous modeling studies usually focused on only one or two physical or biological state variables in the surface waters. Here we used a well‐validated lake biogeochemistry model driven by different climate scenarios of the 21st century to predict the dynamics of ice phenology, water temperature, dissolved oxygen (DO), and chlorophyll a in a small Canadian temperate lake (0.714 km2) that is oligotrophic and strongly stratified in summer, considering the influence of catchment hydrology. The ice season and thickness of the lake are projected to shrink substantially under warming, resulting in a positive energy feedback between climate and the lake. Due to the reduced heat diffusion and water mixing, the dynamics of water temperature in surface and deep waters of the lake are considerably different, with surface waters warmed dramatically but deep waters muted to warming. DO depletion is predicted to occur in the whole water column of the lake under warming, but the controlling processes are depth dependent. Unexpectedly, the predicted growth of the lake's chlorophyll a is small under warming, due to the weakened convection and the mismatch of the timings of favorable solar radiation, thermal, and nutrient conditions. For the examined state variables, our prediction shows that only the dynamics of DO is significantly impacted by the changing catchment hydrology. This study suggests that similar temperate lakes will have diverse physical and biological responses to climate change.

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“…The combined presence of ice cover and a stable stratification in winter has traditionally been assumed to inhibit vertical transport of oxygen from the atmosphere, and hence in shallow lakes, winter anoxic fish kills can occur (Golosov et al, 2007). More recent studies show that increased light levels in late winter lead to under-ice phytoplankton growth (Kim et al, 2015;Obertegger et al, 2017;Phillips & Fawley, 2002;Salmi & Salonen, 2016), which produces oxygen in the upper water column (Pernica et al, 2017). It is likely that the physical processes under the ice (Kirillin et al, 2012) are linked to the timing of the frequent presence of Geophysical Research Letters 10.1002/2017GL075373 large plankton concentrations observed in many lakes during winter (Hampton et al, 2017;Salmi & Salonen, 2016;Twiss et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

High‐Frequency Observations of Temperature and Dissolved Oxygen Reveal Under‐Ice Convection in a Large Lake

Yang

Young

Brown

et al. 2017

Geophysical Research Letters

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Detailed observations of thermal structure over an entire winter in a large lake reveal the presence of large (10-20 m) overturns under the ice, driven by diurnal solar heating. Convection can occur in the early winter, but the most vigorous convection occurred near the end of winter. Both periods are when our lake ice model suggest thinner ice that would have been transparent. This under-ice convection led to a deepening of the mixed layer over time, consistent with previous short-term studies. During periods of vigorous convection under the ice at the end of winter, the dissolved oxygen had become supersaturated from the surface to 23 m below the surface, suggesting abundant algal growth. Analysis of our highfrequency observations over the entire winter of 2015 using the Thorpe-scale method quantified the scale of mixing. Furthermore, it revealed that changes in oxygen concentrations are closely related to the intensity of mixing.

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Dissolved oxygen dynamics under ice: Three winters of high‐frequency data from Lake Tovel, Italy

Cited by 43 publications

References 60 publications

Under‐ice metabolism in a shallow lake in a cold and arid climate

Under‐ice metabolism in a shallow lake in a cold and arid climate

A Small Temperate Lake in the 21st Century: Dynamics of Water Temperature, Ice Phenology, Dissolved Oxygen, and Chlorophyll a

High‐Frequency Observations of Temperature and Dissolved Oxygen Reveal Under‐Ice Convection in a Large Lake

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