Lake Ice—and Ecosystems—in a Warming World

River and Lake Ice Processes—Impacts of Freshwater Ice on Aquatic Ecosystems in a Changing Globe

Water ◽

10.3390/w10111586 ◽

2018 ◽

Vol 10 (11) ◽

pp. 1586 ◽

Cited By ~ 5

Author(s):

Karl-Erich Lindenschmidt ◽

Helen Baulch ◽

Emily Cavaliere

Keyword(s):

Aquatic Ecosystems ◽

Ice Cover ◽

Freshwater Ecosystems ◽

Research Field ◽

Background Information ◽

Special Issue ◽

Physical Processes ◽

Lake Ice ◽

Key Points ◽

Rivers And Lakes

This special issue focuses on the effects of ice cover on surface water bodies, specifically rivers and lakes. Background information on the motivation of addressing this topic is first introduced with some selected references highlighting key points in this research field. A summary and synthesis of the eleven contributions is then provided, focusing on three aspects that provide the structure of the special issue: Physical processes, water quality, and sustainability. We have placed these contributions in the broader context of the field and identified selected knowledge gaps which impede our ability both to understand current conditions, and to understand the likely consequences of changing winters to the diversity of freshwater ecosystems subject to seasonal ice cover.

Download Full-text

Terms and conditions of high-mountain lake ice-cover chemistry (Carpathians, Poland)

Journal of Glaciology ◽

10.3189/2015jog15j045 ◽

2015 ◽

Vol 61 (230) ◽

pp. 1207-1212 ◽

Cited By ~ 1

Author(s):

Iwona Kurzyca ◽

Adam Choiński ◽

Joanna Pociask-Karteczka ◽

Agnieszka Lawniczak ◽

Marcin Frankowski

Keyword(s):

Water Body ◽

Ice Cover ◽

Multilayered Structure ◽

Mountain Lake ◽

High Mountain ◽

Lake Ice ◽

High Mountain Lake ◽

Spatial Diversification ◽

The Tatra Mountains

AbstractWe discuss the results of an investigation of the chemical composition of the ice cover on the high-mountain lake Morskie Oko in the Tatra Mountains, Carpathians, Poland. In the years 2007–13, the ice cover was characterized by an average duration of 6 months, a thickness range of 0.40–1.14 m, and a multilayered structure with water or slush inclusion. In water from the melted ice cover, chloride (max. 69%) and sulphate (max. 51%) anions and ammonium (max. 66%) and calcium (max. 78%) cations predominated. Different concentrations of ions (F−, Cl−, NO3−, SO42−, Na+, K+, Mg2+, Ca2+, NH4+) in the upper, middle and bottom layers of ice were observed, along with long-term variability and spatial diversification within the ice layer over the lake. Snowpack lying on the ice and the water body under the ice were also investigated, and the influence on the ice cover of certain ions in elevated concentrations was observed (e.g. Cl− in the upper ice cover and the snowpack, and Ca2+ in the bottom ice cover and water body).

Download Full-text

Quantitative and qualitative constraints on hind-casting the formation of multiyear lake-ice covers at Lake El'gygytgyn

Climate of the Past ◽

10.5194/cp-9-1253-2013 ◽

2013 ◽

Vol 9 (3) ◽

pp. 1253-1269 ◽

Cited By ~ 15

Author(s):

M. Nolan

Keyword(s):

Water Exchange ◽

Sediment Cores ◽

Ice Cover ◽

Lake Ice ◽

Ice Growth ◽

Temperature Reduction ◽

Air Temperatures ◽

Lake El’Gygytgyn ◽

Oxygen Conditions ◽

Multiyear Ice

Abstract. Analysis of the 3.6 Ma, 318 m long sediment core from Lake El'gygytgyn suggests that the lake was covered by ice for millennia at a time for much of its history and therefore this paper uses a suite of existing, simple, empirical degree-day models of lake-ice growth and decay to place quantitative constraints on air temperatures needed to maintain a permanent ice cover on the lake. We also provide an overview of the modern climatological and physical processes that relate to lake-ice growth and decay as a basis for evaluating past climate and environmental conditions. Our modeling results indicate that modern annual mean air temperature would only have to be reduced by 3.3 °C ± 0.9 °C to initiate a multiyear ice cover and a temperature reduction of at least 5.5 °C ± 1.0 °C is likely needed to completely eliminate direct air–water exchange of oxygen, conditions that have been inferred at Lake El'gygytgyn from the analysis of sediment cores. Once formed, a temperature reduction of only 1–3 °C relative to modern may be all that is required to maintain multiyear ice. We also found that formation of multiyear ice covers requires that positive degree days are reduced by about half the modern mean, from about +608 to +322. A multiyear ice cover can persist even with summer temperatures sufficient for a two-month long thawing period, including a month above +4 °C. Thus, it is likely that many summer biological processes and some lake-water warming and mixing may still occur beneath multiyear ice-covers even if air–water exchange of oxygen is severely restricted.

Download Full-text

Widespread loss of lake ice around the Northern Hemisphere in a warming world

Nature Climate Change ◽

10.1038/s41558-018-0393-5 ◽

2019 ◽

Vol 9 (3) ◽

pp. 227-231 ◽

Cited By ~ 66

Author(s):

Sapna Sharma ◽

Kevin Blagrave ◽

John J. Magnuson ◽

Catherine M. O’Reilly ◽

Samantha Oliver ◽

...

Keyword(s):

Northern Hemisphere ◽

Lake Ice ◽

Warming World

Download Full-text

Big Questions, Few Answers About What Happens Under Lake Ice

Eos ◽

10.1029/2020eo146256 ◽

2020 ◽

Vol 101 ◽

Author(s):

Stephanie Hampton ◽

Stephen Powers ◽

Shawn Devlin ◽

Diane McKnight

Keyword(s):

Ice Cover ◽

Lake Ice ◽

Cold Temperatures

Scientists long eschewed studying lakes in winter, expecting that cold temperatures and ice cover limited activity below the surface. Recent findings to the contrary are changing limnologists’ views.

Download Full-text

Lake ice phenology changes in the northern hemisphere

10.5194/egusphere-egu21-15155 ◽

2021 ◽

Author(s):

Yubao Qiu ◽

Xingxing Wang ◽

Matti Leppäranta ◽

Bin Cheng ◽

Yixiao Zhang

Keyword(s):

Remote Sensing ◽

North America ◽

Northern Hemisphere ◽

Ice Cover ◽

Passive Microwave ◽

Lake Area ◽

Lake Ice ◽

Northern Tibetan Plateau ◽

Break Up ◽

Ice Phenology

<p>Lake-ice phenology is an essential indicator of climate change impact for different regions (Livingstone, 1997; Duguay, 2010), which helps understand the regional characters of synchrony and asynchrony. The observation of lake ice phenology includes ground observation and remote sensing inversion. Although some lakes have been observed for hundreds of years, due to the limitations of the observation station and the experience of the observers, ground observations cannot obtain the lake ice phenology of the entire lake. Remote sensing has been used for the past 40 years, in particular, has provided data covering the high mountain and high latitude regions, where the environment is harsh and ground observations are lacking. Remote sensing also provides a unified data source and monitoring standard, and the possibility of monitoring changes in lake ice in different regions and making comparisons between them. The existing remote sensing retrieval products mainly cover North America and Europe, and data for Eurasia is lacking (Cr&#233;taux et al., 2020).</p><p>Based on the passive microwave, the lake ice phenology of 522 lakes in the northern hemisphere during 1978-2020 was obtained, including Freeze-Up Start (FUS), Freeze-Up End (FUE), Break-Up Start (BUS), Break-Up End (BUE), and Ice Cover Duration (ICD). The ICD is the duration from the FUS to the BUE, which can directly reflect the ice cover condition. At latitudes north of 60&#176;N, the average of ICD is approximately 8-9 months in North America and 5-6 months in Eurasia. Limited by the spatial resolution of the passive microwave, lake ice monitoring is mainly in Northern Europe. Therefore, the average of ICD over Eurasia is shorter, while the ICD is more than 6 months for most lakes in Russia. After 2000, the ICD has shown a shrinking trend, except northeastern North America (southeast of the Hudson Bay) and the northern Tibetan Plateau. The reasons for the extension of ice cover duration need to be analyzed with parameters, such as temperature, the lake area, and lake depth, in the two regions.</p>

Download Full-text

Radiation Transmittance through lake ice in the 400–700 nm Range

Journal of Glaciology ◽

10.3189/s0022143000011229 ◽

1981 ◽

Vol 27 (95) ◽

pp. 57-66 ◽

Cited By ~ 1

Author(s):

S. J. Bolsenga

Keyword(s):

Snow Cover ◽

Ice Cover ◽

Atmospheric Conditions ◽

Lake Ice ◽

Solar Altitude ◽

Ice Surface ◽

New Information ◽

Cloudy Atmosphere ◽

Abrupt Changes ◽

Ann Arbor

AbstractSignificant new information on radiation transmittance through ice in the photosynthetically active range (400–700 nm) has been collected at an inland lake near Ann Arbor, Michigan, U.S.A., and at one site on the Great Lakes (lat. 46° 46´ N., long. 84° 57´ W.). Radiation transmittance through clear, refrozen slush, and brash ice varied according to snow cover, ice type, atmospheric conditions, and solar altitude.Snow cover caused the greatest diminution of radiation. During periods of snow melt, radiation transmittance through snow-covered ice surfaces increased slightly. Moderate diurnal variations of radiation transmittance (about 5%) are attributed to solar altitude changes and associated changes in the direct- diffuse balance of solar radiation combined with the type of ice surface studied. Variations in radiation transmittance of nearly 20% over short periods of time are attributed to abrupt changes from a clear to a cloudy atmosphere.A two-layer reflectance–transmittance model illustrates the interaction of layers in an ice cover such as snow or frost overlying clear ice. Upper layers of high reflectance have considerable control on the overall transmittance and reflectance of an ice cover.

Download Full-text

Calving Seasonality Associated With Melt‐Undercutting and Lake Ice Cover

Geophysical Research Letters ◽

10.1029/2019gl086561 ◽

2020 ◽

Vol 47 (8) ◽

Cited By ~ 2

Author(s):

Joseph Mallalieu ◽

Jonathan L. Carrivick ◽

Duncan J. Quincey ◽

Mark W. Smith

Keyword(s):

Ice Cover ◽

Lake Ice ◽

Lake Ice Cover

Download Full-text

Modeling the impediment of methane ebullition bubbles by seasonal lake ice

Biogeosciences ◽

10.5194/bg-11-6791-2014 ◽

2014 ◽

Vol 11 (23) ◽

pp. 6791-6811 ◽

Cited By ~ 34

Author(s):

S. Greene ◽

K. M. Walter Anthony ◽

D. Archer ◽

A. Sepulveda-Jauregui ◽

K. Martinez-Cruz

Keyword(s):

Growth Rate ◽

Lake Water ◽

Ice Cover ◽

Controlling Factors ◽

Ch4 Emission ◽

Lake Ice ◽

Ch4 Emissions ◽

Interior Alaska ◽

Methane Ebullition ◽

Significant Flux

Abstract. Microbial methane (CH4) ebullition (bubbling) from anoxic lake sediments comprises a globally significant flux to the atmosphere, but ebullition bubbles in temperate and polar lakes can be trapped by winter ice cover and later released during spring thaw. This "ice-bubble storage" (IBS) constitutes a novel mode of CH4 emission. Before bubbles are encapsulated by downward-growing ice, some of their CH4 dissolves into the lake water, where it may be subject to oxidation. We present field characterization and a model of the annual CH4 cycle in Goldstream Lake, a thermokarst (thaw) lake in interior Alaska. We find that summertime ebullition dominates annual CH4 emissions to the atmosphere. Eighty percent of CH4 in bubbles trapped by ice dissolves into the lake water column in winter, and about half of that is oxidized. The ice growth rate and the magnitude of the CH4 ebullition flux are important controlling factors of bubble dissolution. Seven percent of annual ebullition CH4 is trapped as IBS and later emitted as ice melts. In a future warmer climate, there will likely be less seasonal ice cover, less IBS, less CH4 dissolution from trapped bubbles, and greater CH4 emissions from northern lakes.

Download Full-text

Simulation of North American lake-ice cover characteristics under contemporary and future climate conditions

International Journal of Climatology ◽

10.1002/joc.2300 ◽

2011 ◽

Vol 32 (5) ◽

pp. 695-709 ◽

Cited By ~ 33

Author(s):

Yonas Dibike ◽

Terry Prowse ◽

Barrie Bonsal ◽

Laurent de Rham ◽

Tuomo Saloranta

Keyword(s):

North American ◽

Ice Cover ◽

Future Climate ◽

Lake Ice ◽

Climate Conditions ◽

Lake Ice Cover

Download Full-text