Winter Limnology: How do Hydrodynamics and Biogeochemistry Shape Ecosystems Under Ice?

Jansen, Joachim; MacIntyre, Sally; Barrett, David C.; Chin, Yu‐Ping; Cortés, Antonio José Pérez; Forrest, Alexander L.; Hrycik, Allison R.; Martin, Rosemary; McMeans, Bailey; Rautio, Milla; Schwefel, Robert

doi:10.1029/2020jg006237

Cited by 61 publications

(42 citation statements)

References 255 publications

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“…Santibáñez et al (2019) showed experimentally that bacteria were preferentially incorporated into lake ice during freezing and that this was mainly controlled by the solute concentration of major ions in the liquid water source; the higher the ion concentration in water the more readily the bacteria were incorporated into the ice. Cryoconcentration, the exclusion of solutes when ice freezes, contributes to an increased solute concentration at the ice-water interface (Jansen et al, 2021), which in turn may favor bacterial incorporation into the ice.…”

Section: 1029/2020jg006233 11 Of 18mentioning

confidence: 99%

Hidden Stores of Organic Matter in Northern Lake Ice: Selective Retention of Terrestrial Particles, Phytoplankton and Labile Carbon

et al. 2021

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Over the last few decades, global warming has led to widespread shrinking of the cryosphere and has brought a sense of urgency toward the study of ice habitats. One of the most heavily impacted cryospheric habitats is freshwater ice. Climate change is leading to substantial reductions in the thickness and duration of lake and river ice cover worldwide (Sharma et al., 2019;Wrona et al., 2016). In the northern hemisphere, ice in lakes and rivers freezes an average of 5.8 days later and melts 6.5 days earlier than 100 years ago, based on the measurements taken between the years 1846and 1995(Magnuson, et al., 2000. Global air temperatures increased 1.2°C during this period. The majority of boreal and Arctic lakes are still ice-covered for six to ten months a year, and the potential importance of this cold and dark period on ecosystem structure and function is increasingly recognized (Grosbois & Rautio, 2018;Hampton et al., 2017;Schneider et al., 2017). Considering that ice-covered lakes include nearly 50% of the world's lakes, there is a pressing Abstract Around 50% of the world's lakes freeze seasonally, but the duration of ice-cover is shortening each year and this is likely to have broad limnological consequences. We sampled freshwater ice and the underlying water in 19 boreal and polar lakes to evaluate whether lake ice contains an inoculum of algae, nutrients, and carbon that may contribute to lake ecosystem productivity. Boreal and Arctic lakes differed in ice duration (6 vs. >10 months), thickness (70 vs. 190 cm), and quality (predominantly snow ice vs. black ice), but in all lakes, there were consistent differences in biological and biogeochemical composition between ice and water. Particulate fractions were often more retained while most dissolved compounds were excluded from the ice; for example, the ice had more terrestrial particulate carbon, measured as fatty acid biomarkers (averages of 1.1 vs. 0.3 µg L −1 ) but lower dissolved organic carbon (2.2 vs. 5.7 mg C L −1 ) and inorganic phosphorus concentrations (4.0 vs. 7.5 µg C L −1 ) than the underlying water. The boreal ice further had three times higher chlorophyll-a, than the water (0.9 vs. 0.3 µg L −1 ). Of the dissolved fractions, the contribution of protein-like compounds was higher in the ice, and this in all lakes. These labile compounds would become available to planktonic microbes when the ice melts. Our results show that freshwater ice has an underestimated role in storage and transformation in the biogeochemical carbon cycle of ice-covered lake ecosystems.Plain Language Summary Winter ice cover of 1-2 m thickness can comprise 20%-70% of the total lake depth in boreal and Arctic lakes. While sea ice is known to contain substantial quantities of carbon and organisms that at ice melt contribute to biological production in the underlying water column, little is known about the composition of lake ice and its role in storage of organic carbon. Our analyses of 19 boreal and Arctic lakes revealed large but different stores of organic material in lake ...

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Section: 1029/2020jg006233 11 Of 18mentioning

confidence: 99%

Hidden Stores of Organic Matter in Northern Lake Ice: Selective Retention of Terrestrial Particles, Phytoplankton and Labile Carbon

et al. 2021

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“…75 Although our measurements captured only the icefree summer behavior of redox-active solutes, it is highly likely that they are inuenced by winter hydrodynamics. 74,76,77 Future studies will be paramount in linking winter hydrodynamics, mixing, and hydrology to biogeochemical cycling in order to determine the effect of decreasing ice cover on methane production within Arctic lake sediments. Previous studies have linked methane transport from active layers of permafrost thaw and ground water into near shore, shallow areas of Toolik Lake.…”

Section: Environmental Implicationsmentioning

confidence: 99%

Spatial distribution and biogeochemistry of redox active species in arctic sedimentary porewaters and seeps

Hudson

Michaud

Emerson

et al. 2022

Environ. Sci.: Processes Impacts

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“…Ice can be present or absent, it can cover a lake for a long time or a short time, and it can vary from optically transparent columnar ice ("black ice") to more opaque ("white ice"), all with important implications for biological, chemical, and physical processes. The review and synthesis by Jansen et al (2021) focused on developing an integrative understanding of how physical processes in lakes in winter are linked to biogeochemical and ecological dynamics. Primary drivers such as light availability and distribution of heat within the water column have cascading effects on critical chemical parameters such as redox state, which impacts both nutrients and predominant metabolic processes including aerobic respiration, nitrification-denitrification coupling, methane oxidation (Sawakuchi et al, 2021), and other anaerobic metabolisms such as methanogenesis, sulfate reduction, anoxygenic photosynthesis, and anammox.…”

Section: Concepts and Synthesesmentioning

confidence: 99%

Whither Winter: The Altered Role of Winter for Freshwaters as the Climate Changes

et al. 2022

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Our changing climate is having effects on freshwater ecosystems in all seasons, especially winter. High latitude lakes, wetlands, and rivers are experiencing shorter periods of ice cover, and lower latitudes systems that used to freeze are experiencing open water conditions throughout the winter. A 2019 AGU Chapman conference convened aquatic scientists to examine these changes and address the implications of changing winters to aquatic life, chemistry, and physics. Several studies demonstrate decreased ice cover duration than in the past. The removal of an ice “lid” from lakes and rivers impacts the exchange of gases with the atmosphere and the predominant types of metabolism occurring in the waters below, with the potential for more photosynthesis and an increase in oxic versus anoxic metabolism when the lid is removed. Multiple studies indicated an increase in the interannual variability of winters, especially in terms of ice‐cover duration and ice quality. Increased variability may simply be an outcome of a more variable winter climate or small differences in environmental conditions such as temperature that can have strong effects on gas exchange, light transmission, and turbulence when ice forms. A question that merits further consideration is whether and how winters of shorter duration and severity will change the dynamics of freshwater systems. Are there memory or legacy effects that carry over to the next season or year? There is much work to be done to understand how changing winters will impact the biogeochemical behavior of lakes and rivers in the coming decades.

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Winter Limnology: How do Hydrodynamics and Biogeochemistry Shape Ecosystems Under Ice?

Cited by 61 publications

References 255 publications

Hidden Stores of Organic Matter in Northern Lake Ice: Selective Retention of Terrestrial Particles, Phytoplankton and Labile Carbon

Hidden Stores of Organic Matter in Northern Lake Ice: Selective Retention of Terrestrial Particles, Phytoplankton and Labile Carbon

Spatial distribution and biogeochemistry of redox active species in arctic sedimentary porewaters and seeps

Whither Winter: The Altered Role of Winter for Freshwaters as the Climate Changes

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