Your search keyword '"Lake ice"' showing total 306 results

1. The state and fate of lake ice thickness in the Northern Hemisphere

Author

Xingdong Li, Fanyu Zhao, Di Long, and Qi Huang

Subjects

Multidisciplinary, Climate, Ice, Global warming, Northern Hemisphere, Lake ecosystem, Grid cell, Radiative forcing, Global Warming, Ice thickness, Lakes, General Circulation Model, Humans, Environmental science, Lake ice, Physical geography, Ecosystem

Abstract

Lake ice thickness (LIT) is important for regional hydroclimate systems, lake ecosystems, and human activities on the ice, and is thought to be highly susceptible to global warming. However, the spatiotemporal variability in LIT is largely unknown due to the difficulty in deriving in situ measurements and the lack of an effective remote sensing platform. Despite intensive development and applications of lake ice models driven by general circulation model output, evaluation of the global LIT is mostly based on assumed “ideal” lakes in each grid cell of the climate forcing data. A method for calculating the actual global LIT is therefore urgently needed. Here we use satellite altimetry to retrieve ice thickness for 16 large lakes in the Northern Hemisphere (Lake Baikal, Great Slave Lake, and others) with an accuracy of ∼0.2 m for almost three decades. We then develop a 1-D lake ice model driven primarily by remotely sensed data and cross-validated with the altimetric LIT to provide a robust means of estimating LIT for lakes larger than 50 km2 across the Northern Hemisphere. Mean LIT (annual maximum ice thickness) for 1313 simulated lakes and reservoirs covering ∼840,000 km2 for 2003–2018 is 0.63 ± 0.02 m, corresponding to ∼485 Gt of water. LIT changes are projected for 2071–2099 under RCPs 2.6, 6.0, and 8.5, showing that the mean LIT could decrease by ∼0.35 m under the worst concentration pathway and the associated lower ice road availability could have a significant impact on socio-economic activities.

Published

2022

2. Simple Method to Extract Lake Ice Condition From Landsat Images

Author

Xiao Yang, Tamlin M. Pavelsky, Shuai Zhang, and Liam Bendezu

Subjects

Biogeochemical cycle, Quality assessment, Remote sensing (archaeology), Satellite remote sensing, General Earth and Planetary Sciences, Lake ice, Physical geography, Electrical and Electronic Engineering, Snow, Geology

Abstract

Ice plays key roles in regulating hydrological, ecological, biogeochemical, and socioeconomic functions of lakes. Long-term in situ lake ice phenological records indicate that lake ice is trending toward later freeze-up, earlier breakup, and a shorter ice duration. Parallel to study of lake ice using in situ records and process-based models, satellite remote sensing can expand our understanding of lake ice change over large spatial scales. However, most remote sensing studies have focused on large lakes or short periods of time, which may not robustly represent changes over multidecadal time periods or in the much more numerous small lakes. Here, we present a random forest model, Sensitive Lake Ice Detection (SLIDE), to accurately extract ice conditions from Landsat TM, ETM+, and OLI images. We trained the model using a manually labeled lake ice dataset (1089 labeled areas over 995 lakes globally). Our results show that our model achieves accurate classification between ice/snow and water (accuracy: 97.8%, kappa coefficient: 95.5%). Comparing Landsat-derived ice cover with in situ ice conditions, we show that our model produces less bias, lower RMSE, and higher kappa than does the Landsat snow/ice flag from the quality assessment band. This is especially true during the transitional period surrounding the ice on and off dates reported from in situ (mean bias -7.3% from our model, -17.3% from the Landsat quality band). Our results demonstrate the feasibility of mining the rich Landsat archive to study lake ice dynamics and of better flagging ice-affected lake observations.

Published

2022

3. A new finding on the prevalence of rapid water warming during lake ice melting on the Tibetan Plateau

Author

Juzhi Hou, Kun Yang, Yingying Chen, Junbo Wang, Lazhu, Mingda Wang, Liping Zhu, Xiaogang He, and Yanbin Lei

Subjects

geography, Multidisciplinary, Plateau, geography.geographical_feature_category, Lake ice, Physical geography, Geology

Published

2021

4. Contrasting Lake Ice Phenology Changes in the Qinghai–Tibet Plateau Revealed by Remote Sensing

Author

Chuan Xiong, Yonghui Lei, and Yubao Qiu

Subjects

geography, Plateau, geography.geographical_feature_category, Phenology, Climate change, Geotechnical Engineering and Engineering Geology, Proxy (climate), Salinity, Remote sensing (archaeology), Period (geology), Lake ice, Environmental science, Physical geography, Electrical and Electronic Engineering

Abstract

Lake ice phenology is regarded as a good proxy for the past and present climates. Long time series passive microwave radiometry data are used to estimate lake ice phenology variations in the Qinghai–Tibet Plateau (QTP), and a contrasting pattern of phenology change trend is found that the time series trend of lake ice freeze-up or break-up time is obviously reversed for lakes in the QTP. The reason for this contrasting trend of lake ice phenology is discussed based on factors such as salinity, water volume change, and air temperature change. Lake ice phenology data are separated based on lake salinity for the climate study: lake ice phenology of lakes with low salinity can be used as air temperature and climate change indicator, whereas lake ice phenology of lakes with high salinity and a low water volume can be used as an indicator of water volume variation under climate change. Correlation analysis of air temperature and the lake ice phenology show that air temperature is the main driving factor behind lake ice phenology variations. The lake ice phenology results suggest overall rising air temperatures during the period 1987–2017 in all regions of the QTP.

Published

2021

5. Deep convolutional neural network with random field model for lake ice mapping from Sentinel-1 imagery

Author

Rui Wu, Claude R. Duguay, Yiyi Ma, Ye Chen, Kui Li, Zihao Liu, Zhiguo Ma, Linlin Xu, Linglong Wangqu, and Jiabin Pu

Subjects

Random field, Cover (telecommunications), Fishing, General Earth and Planetary Sciences, Lake ice, Physical geography, Convolutional neural network, Geology

Abstract

Timely information on lake ice cover conditions is critical in support of commercial shipping, winter-road transportation, and winter leisure activities such as snowmobiling and ice fishing. Monito...

Published

2021

6. The littoral zone of polar lakes: inshore–offshore contrasts in an ice-covered High Arctic lake

Author

Warwick F. Vincent, Milla Rautio, Alexander I. Culley, Yukiko Tanabe, Masaki Uchida, and Paschale Noël Bégin

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, underwater light, Environmental engineering, 01 natural sciences, Spring (hydrology), Littoral zone, GE1-350, lake zonation, 0105 earth and related environmental sciences, General Environmental Science, lake ice, geography, geography.geographical_feature_category, 010604 marine biology & hydrobiology, microbial mats, TA170-171, Environmental sciences, Oceanography, Arctic, food webs, General Earth and Planetary Sciences, Polar, Submarine pipeline, General Agricultural and Biological Sciences, human activities, Geology

Abstract

In ice-covered polar lakes, a narrow ice-free moat opens up in spring or early summer, and then persists at the edge of the lake until complete ice loss or refreezing. In this study, we analyzed the horizontal gradients in Ward Hunt Lake, located in the Canadian High Arctic, and addressed the hypothesis that the transition from its nearshore open-water moat to offshore ice-covered waters is marked by discontinuous shifts in limnological properties. Consistent with this hypothesis, we observed an abrupt increase in below-ice concentrations of chlorophyll a beyond the ice margin, along with a sharp decrease in temperature and light availability and pronounced changes in benthic algal pigments and fatty acids. There were higher concentrations of rotifers and lower concentrations of viruses at the ice-free sampling sites, and contrasts in zooplankton fatty acid profiles that implied a greater importance of benthic phototrophs in their inshore diet. The observed patterns underscore the structuring role of ice cover in polar lakes. These ecosystems do not conform to the traditional definitions of littoral versus pelagic zones but instead may have distinct moat, ice-margin, and ice-covered zones. This zonation is likely to weaken with ongoing climate change.

Published

2021

7. Characteristics and influencing factors of lake ice growth and decay in a shallow lake from a cold region*

Author

Zhang Yiwen, Li Zhijun, Zu Yongheng, Cao Xiaowei, Lu Peng, and Xie Fei

Subjects

Oceanography, Earth and Planetary Sciences (miscellaneous), Lake ice, Aquatic Science, Shallow lake, Pollution, Geology, Water Science and Technology

Published

2021

8. Fasting or feeding: A planktonic food web under lake ice

Author

M. T. Syarki, Natalia Kalinkina, Damien Bouffard, Emilie Lyautey, Victor Frossard, Marie-Elodie Perga, Jorge E. Spangenberg, Université de Lausanne (UNIL), Northern Water Problems Institute, RAS, Partenaires INRAE, Centre Alpin de Recherche sur les Réseaux Trophiques et Ecosystèmes Limniques (CARRTEL), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), and Swiss Federal Insitute of Aquatic Science and Technology [Dübendorf] (EAWAG)

Subjects

zooplankton, 0106 biological sciences, CS-SIA, diel vertical migration, table isotope, winter limnology, zooplankton, table isotope, CS-SIA, 010604 marine biology & hydrobiology, Aquatic Science, Plankton, 010603 evolutionary biology, 01 natural sciences, Zooplankton, Food web, diel vertical migration, Oceanography, Environmental science, Lake ice, 14. Life underwater, winter limnology, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, Diel vertical migration

Abstract

International audience; Zooplankton can spend winter actively under the ice cover of lakes. However, dietary resources under lake ice are both quantitatively and qualitatively limited, and feeding might not be energetically rewarding for most zooplankton species. Many zooplankters are expected to fast throughout the winter, exhausting their previously accumulated fat storage. We hypothesised that only a fraction of the actively overwintering zooplankton contributes to an active food web under lake ice, leading to few trophic linkages within the planktonic community.2. Zooplankton habitats and feeding were investigated under the ice of Lake Onego. Zooplankton habitats and migrations were studied by coupling zooplankton sam-pling around the clock to measurements of particle movement using an acoustic Doppler current profiler. Secondly, fatty acid-specific stable isotope compositions were used to determine whether and which zooplankton fatty acids ultimately came from the assimilation of under-ice seston.3. The algal biomass was low under ice and mostly dominated by large diatoms. Copepods dominated the zooplankton community. Species present as late cope-podite and adult instars were confined to the deeper layers, while nauplii occupied the surface layer. Diel vertical migration by Cyclops was the most tangible ob-servation of persistent feeding under the ice. Previously accumulated fat storage represented most of zooplankton fatty acids, with few, yet detectable, fatty acids recently acquired by feeding under the ice.4. Although some zooplankton taxa maintained feeding activity under the ice of Lake Onego, the food source available beneath the ice was not sufficiently rewarding to leave an isotopic imprint upon the dominant fatty acids of bulk zooplankton. The seston fatty acids that were passed on to zooplankton from feeding under ice were not provided by diatoms, although they made up most of the phytoplank-ton biovolume. Instead, the zooplankton food web was supported by mixotrophic phytoplankton (i.e. cryptophytes and chrysophytes) that represented

Published

2020

9. Retrieval of ice/water observations from synthetic aperture radar imagery for use in lake ice data assimilation

Author

Homa Kheyrollah Pour, Linlin Xu, and K. Andrea Scott

Subjects

0106 biological sciences, Synthetic aperture radar, Ecology, 010604 marine biology & hydrobiology, 010501 environmental sciences, Aquatic Science, 01 natural sciences, Convolutional neural network, Ice water, Data assimilation, Lake ice, Satellite imagery, Sea ice concentration, Ecology, Evolution, Behavior and Systematics, Geology, Synthetic aperture radar imagery, 0105 earth and related environmental sciences, Remote sensing

Abstract

High-resolution lake ice/water observations retrieved from satellite imagery through efficient, automated methods can provide critical information to lake ice forecasting systems. Synthetic aperture radar (SAR) data is well-suited to this purpose due to its high spatial resolution (approximately 50 m). With recent increases in the volume of SAR data available, the development of automated retrieval methods for these data is a priority for operational centres. However, automated retrieval of ice/water data from SAR imagery is difficult, due to ambiguity in ice and open water signatures, both in terms of image tone and in terms of parameterized texture features extracted from these images. Convolutional neural networks (CNNs) can learn features from imagery in an automated manner, and have been found effective in previous studies on sea ice concentration estimation from SAR. In this study the use of CNNs to retrieve ice/water observations from dual-polarized SAR imagery of two of the Laurentian Great Lakes, Lake Erie and Lake Ontario, is investigated. For data assimilation, it is crucial that the retrieved observations are of high quality. To this end, quality control measures based on the uncertainty of the CNN output to eliminate incorrect retrievals are discussed and demonstrated. The quality control measures are found to be effective in both dual-polarized and single-polarized retrievals. The ability of the CNN to downscale the coarse resolution training labels is demonstrated qualitatively.

Published

2020

10. Cyclic strengthening of lake ice

Author

Carl E. Renshaw, Andrii Murdza, Erland M. Schulson, and Aleksey Marchenko

Subjects

Stress (mechanics), Amplitude, 010504 meteorology & atmospheric sciences, Flexural strength, Fresh water, Range (biology), Lake ice, Composite material, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Further to systematic experiments on the flexural strength of laboratory-grown, fresh water ice loaded cyclically, this paper describes results from new experiments of the same kind on lake ice harvested in Svalbard. The experiments were conducted at −12 °C, 0.1 Hz frequency and outer-fiber stress in the range from ~ 0.1 to ~ 0.7 MPa. The results suggest that the flexural strength increases linearly with stress amplitude, similar to the behavior of laboratory-grown ice.

Published

2020

11. Solar radiation transfer for an ice-covered lake in the central Asian arid climate zone

Author

Matti Leppäranta, Xiaohong Shi, Lauri Arvola, Jussi Huotari, Xiaowei Cao, Peng Lu, Zhijun Li, Guoyu Li, Institute for Atmospheric and Earth System Research (INAR), Lammi Biological Station, and Biological stations

Subjects

1171 Geosciences, 010504 meteorology & atmospheric sciences, irradiance, 0207 environmental engineering, Irradiance, 02 engineering and technology, snow, Aquatic Science, Inner mongolia, Atmospheric sciences, 114 Physical sciences, 01 natural sciences, OXYGEN, transmittance, WATER, 020701 environmental engineering, Shallow lake, TEMPERATURE, 0105 earth and related environmental sciences, Water Science and Technology, lake ice, Desert climate, OPTICAL-PROPERTIES, 15. Life on land, Albedo, Snow, SHALLOW LAKE, Radiation transfer, 13. Climate action, Environmental science, Lake ice, absorption, albedo

Abstract

Spectral albedo and light transmittance through snow, ice, and water were measured in Lake Wuliangsuhai (40 degrees 36 '-41 degrees 30 ' N, 108 degrees 43 '-108 degrees 70 ' E), Inner Mongolia, China, during winter 2016. Data on the weather, structure of lake ice, and geochemistry of water were also collected during the 60-day field program. The study lake is shallow (mean depth 1.0-1.5 m) with a large wetland area. Compared with polar lakes, solar elevation is higher, snow accumulation is much lower, and the ice has more sediment. The ice was all congelation ice with a mean thickness of 36.6 cm, corresponding to a mean air temperature of -9.6 degrees C. The mean daily broadband albedo and photosynthetically active radiation (PAR) band transmittance were 0.54 and 0.08 (bare ice), 0.74 and 0.04 (new snow), and 0.30 and 0.12 (melting period), respectively. The level of light allowed photosynthesis to occur to the bottom of the lake. The ice acted as a grey filter for the sunlight with a mean attenuation coefficient of 2.1 m(-1). These results expand our knowledge of the evolution of light transfer through ice and snow cover and its role in the ecology of lakes in temperate and arid areas.

Published

2020

12. Air/snow, snow/ice and ice/water interfaces detection from high-resolution vertical temperature profiles measured by ice mass-balance buoys on an Arctic lake

Author

Timo Vihma, Fei Zheng, Anna Kontu, Yubing Cheng, Qinghua Yang, Zeliang Liao, and Bin Cheng

Subjects

Snow ice, 010504 meteorology & atmospheric sciences, Freeboard, 0208 environmental biotechnology, High resolution, 02 engineering and technology, Atmospheric sciences, Snow, 01 natural sciences, Ice water, 020801 environmental engineering, Arctic, Ice mass balance, Lake ice, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Snow and ice were monitored by thermistor-string-based Snow and Ice Mass Balance Array (SIMBA) in Lake Orajärvi in northern Finland. An existing automatic SIMBA-algorithm was further developed to derive air/snow, snow/ice and ice/water interfaces based on the SIMBA environment temperature (ET) profiles. The identified interfaces agreed with in situ observations made in 2011/12 winter season. The method was capable to identify upward-moving snow/ice interface that was also visible from SIMBA heating temperature (HT) profiles, which responds to differences in the thermal diffusivities of air, snow, ice and water. The SIMBA data obtained in winters 2017/18 and 2018/19 were used to investigate snow and ice mass balance. An upward-moving snow/ice interface was detected as a result of meteoric ice (snow ice and superimposed ice) formation. Snow contributed to granular lake ice formation up to 40–55% of the total ice thickness on the seasonal mean. Heavy snowfalls and low air temperature in early winter are favourable for granular ice formation. The seasonal mean snow depth on nearby land was 2.7–2.9 times of that on the lake. The estimation of freeboard from snow and ice mass-balance measurement is sensitive to the snow density. Accurate ice freeboard calculation is still a challenge.

Published

2020

13. The Impact of Preceding Spring Antarctic Oscillation on the Variations of Lake Ice Phenology over the Tibetan Plateau

Author

Huopo Chen, Huijun Wang, Yong Liu, and Huixin Li

Subjects

Atmospheric Science, geography, Plateau, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Phenology, Atmospheric circulation, Climate change, 010502 geochemistry & geophysics, 01 natural sciences, Climatology, Spring (hydrology), Environmental science, Lake ice, Antarctic oscillation, 0105 earth and related environmental sciences, Teleconnection

Abstract

The lake ice phenology response to climate change has been receiving growing concern in recent years. However, most studies have put emphasis on the spatial and temporal variability of lake ice phenology, and relatively few studies have been devoted to investigating the physical mechanisms of changes in lake ice phenology from the perspective of climatic dynamics. This study investigates the possible impact of the Antarctic Oscillation (AAO) on the variations in lake ice phenology over the Tibetan Plateau (TP). The results show that there is an intimate relationship between the AAO and the variations in break-up/ice duration during the period 2003–15. Further analysis indicates that the preceding boreal spring AAO-induced atmospheric circulation anomalies are favorable for generating tropical South Atlantic Ocean SST anomalies through air–sea interaction. Then the tropical SST anomalies strengthen the anomalous local-scale meridional–vertical circulation that projects into the Azores high and further induce the extratropical portion of the North Atlantic SST tripole. The anomalous warm core in the North Atlantic serves as the source of wave activity flux and stimulates a stationary wave train along the Eurasian continent to change the downstream atmospheric circulation. As a response, an abnormal cyclone and enhanced updraft are triggered over the TP, which are favorable for the formation of snowfall and then lower the surface air temperature according to the snow-albedo feedback mechanism, and thus result in the prolonged lake ice duration events. This study provides a new insight to link the AAO influence and climate over the TP and is helpful to understand the changes in lake ice phenology in response to climate change in recent years.

Published

2020

14. Interannual Variability of Lake Ice Backscatter Anomalies on Lake Neyto, Yamal, Russia

Author

Pointner, Georg and Bartsch, Annett

Subjects

Oceanography, Backscatter, Geography, Planning and Development, Lake ice, Computers in Earth Sciences, Geology, Computer Science Applications, Education

Abstract

Anomalous areas of varying shape and location characterized by low backscatter in Synthetic Aperture Radar (SAR) imagery of lake ice on lake Neyto on the Yamal Peninsula in Russia have been described qualitatively in the literature for many years. Possible suggested causes are the formation of eddies or the release of gas through the lake sediments, which could both lead to local thinning of the ice layer and alter radar backscatter. To date, the phenomenon, its cause, and its spatial and temporal dynamics are poorly understood, and studies from other geographic regions are completely absent. In order to perform first steps towards a better understanding of the phenomenon, we developed a workflow to quantitatively assess the spatial variability of the anomalies in the years 2015 to 2019 for lake Neyto. We introduce a binary image classification algorithm developed with state-of-the-art open-source image processing tools and employ metrics commonly used for describing spatial relationships of vector and raster data. This includes polygon distances, polygon intersections and cumulative pixel counts deduced from the classification results in order to quantify, for the very first time, the dynamics over a number of years. The geospatial analysis reveals large spatial variations, but also some overlap between different years. Locations of anomalies do not seem more similar between consecutive years than when they are compared over the longer period. Some of the spatial properties of the clusters of low backscatter may support the explanation of gas release as the primary cause of the observed patterns.

Published

2020

15. Lake Ice Formation and Melt. Under-Ice Dynamics

Author

Matti Leppäranta and Georgiy Kirillin

Subjects

Ice dynamics, Oceanography, Lake ice, Geology

Published

2022

16. Recent Development in Ice Engineering

Author

Li Zhou

Subjects

River ice, Drift ice, geography, geography.geographical_feature_category, Climatology, Sea ice, Lake ice, Snow, Geology, Icing

Abstract

Ice Engineering is associated with how to solve challenges from different kinds of ice, such as, sea ice, river ice, lake ice, icing, and snow in cold regions. The aim is to design special structures which could resist structural and global impact from drifting ice and freezing ice.

Published

2021

17. Changing Lake Ice Intermittency in the Northern Hemisphere

Author

Nadir Jeevanjee, Sirisha Kalidindi, Grace Liu, and Gabriel A Vecchi

Subjects

Oceanography, law, Intermittency, Northern Hemisphere, Lake ice, Geology, law.invention

Abstract

As the global climate warms, lakes are expected and have been observed to experience changes in seasonal ice cover. Previous research has observed decreasing freeze durations, but relatively few studies have investigated the impact of climate change on lake ice intermittency - the tendency of lakes to freeze over in some years but not others. Here we conduct an analysis of a lake dataset that includes nineteen intermittent ice-covered lakes in the northern hemisphere. We use logistic and binomial regression to model the relationship between historical climate changes and freeze events, with log CO2 concentration and mean winter temperature as covariates. Across the lakes, we observe a decrease in freeze probability and years with freeze events, with nine out of nineteen lakes showing a significant relationship between freeze years and log CO2 concentration. Additionally, we find that mean winter temperature can be a simple, readily accessible predictor for intermittent lake freeze. We also examine Lake Carnegie in Princeton, NJ as a case study, taking into account both quantitative data and anecdotal evidence, and find that the probability of ice skating has decreased from nearly 1 to 0.2 over the past century. Accordingly, local newspaper archives semantically suggest that local expectations for lake freezing have reversed over the last century as a societal response to climate change.

Published

2021

18. The Lake Ice Continuum Concept: Influence of Winter Conditions on Energy and Ecosystem Dynamics

Author

Catherine M. O'Reilly, E. Cavaliere, S. M. Powers, Steve Sadro, Stella A. Berger, Noah R. Lottig, Stephanie E. Hampton, Milla Rautio, G. P. Rue, Bailey C. McMeans, I. B. Fournier, Hilary A. Dugan, V. Hazuková, Tedy Ozersky, and James B. Cotner

Subjects

Atmospheric Science, Ecology, Ecology (disciplines), Paleontology, Soil Science, Biogeochemistry, Forestry, Continuum concept, Aquatic Science, Energy (psychological), Oceanography, Ecosystem dynamics, Environmental science, Lake ice, Water Science and Technology

Published

2021

19. High‐Resolution Mapping of Ice Cover Changes in Over 33,000 Lakes Across the North Temperate Zone

Author

Junguo Liu, Chunmiao Zheng, Xinchi Wang, Zhenzhong Zeng, Wei Qi, Luke Gibson, Yi Zheng, Lian Feng, and Jing Tang

Subjects

Geophysics, Phenology, Global warming, Period (geology), Temperate climate, General Earth and Planetary Sciences, Environmental science, High resolution, Climate change, Lake ice, Physical geography

Abstract

More than 50% of global lakes periodically freeze, and their lake ice phenology is sensitive to climate change. However, spatially detailed quantification of the changes in lake ice at the global scale is not available. Here, we map ice cover in >33,000 lakes throughout the North Temperate Zone (23.5°–66.5°N) using 0.55 million Landsat images from 1985 to 2020. Over this period, we found a remarkable reduction in median ice cover occurrence (ICO) (61% to 43%), which was strongly related to warming terrestrial mean surface temperatures (R2 = 0.94, p < 0.05). Lakes in Europe showed the most pronounced ice loss (median ICO decreased from 50% to 24%), and extensive lake ice losses were also detected in the northern US, and central and eastern Asia. An overall increase in ice cover was identified from P2 (1999–2006) to P3 (2007–2014) due to regional decreased temperatures associated with the “global warming hiatus.” Thehigh-resolution mapping of lake ice here provides essentialbaseline information whichcan be used to elucidate ice loss-induced environmental and societal impacts. (Less)

Published

2021

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

Author

Maxime Wauthy, Milla Rautio, Elise Imbeau, Mathieu Cusson, and Warwick F. Vincent

Subjects

0106 biological sciences, chemistry.chemical_classification, Atmospheric Science, 010504 meteorology & atmospheric sciences, Ecology, 010604 marine biology & hydrobiology, Paleontology, Soil Science, chemistry.chemical_element, Forestry, Aquatic Science, 01 natural sciences, Selective retention, chemistry, Environmental chemistry, Phytoplankton, Environmental science, Lake ice, Organic matter, Carbon, 0105 earth and related environmental sciences, Water Science and Technology

Published

2021

21. Ice‐Covered Lakes of Tibetan Plateau as Solar Heat Collectors

Author

Tom Shatwell, Georgiy Kirillin, and Lijuan Wen

Subjects

geography, Geophysics, Plateau, geography.geographical_feature_category, Thermal, Solar heat, General Earth and Planetary Sciences, Lake ice, Atmospheric sciences, Geology

Abstract

The Qinghai-Tibet Plateau possesses the largest alpine lake system, which plays a crucial role in the land-atmosphere interaction. We report first observations on the thermal and radiation regime u...

Published

2021

22. Approximating Lake Ice Phenology with Satellite Surface Temperature Data

Author

Sophia Karina Skoglund, Linda C. Bacon, Bethel G. Steele, A. R. Bah, Kathleen C. Weathers, Hamidreza Norouzi, and Holly A. Ewing

Subjects

Daytime, 010504 meteorology & atmospheric sciences, Phenology, 0211 other engineering and technologies, 02 engineering and technology, 01 natural sciences, Temperature measurement, 13. Climate action, Moving average, Climatology, Lake ice, Environmental science, Satellite, Moderate-resolution imaging spectroradiometer, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

Studies of lake ice phenology have historically relied on limited in situ data. Satellite-derived temperature data provide an opportunity to better understand the climatological factors and trends behind ice phenology. Here we developed a model that uses daytime and nighttime surface temperature observations from the Moderate Resolution Imaging Spectroradiometer (MODIS) sensor onboard Aqua to approximate ice in for 13 lakes and ice out for 58 lakes in Maine from 2002–2018. Ice-in and ice-out approximations were signaled by a moving average of the data crossing the 0°C threshold. The comparison of in situ and satellite-derived ice-out and ice-in dates were both highly correlated, but the amount of bias in those estimates was influenced by the number of days in a moving average of temperature. Systematic biases in the approximation model toward predicting ice in too early and ice out too late point to the importance of in-lake dynamics in modifying the timing of stabilization or melting of ice.

Published

2021

23. Climate Change is Contributing to Faster Rates of Lake Ice Loss in Lakes Around the Northern Hemisphere

Author

Sapna Sharma and Mohammad Arshad Imrit

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Ecology, 0207 environmental engineering, Northern Hemisphere, Paleontology, Soil Science, Climate change, Forestry, 02 engineering and technology, Aquatic Science, 01 natural sciences, Environmental science, Lake ice, Physical geography, 020701 environmental engineering, 0105 earth and related environmental sciences, Water Science and Technology

Published

2021

24. Differential Heating Drives Downslope Flows that Accelerate Mixed‐Layer Warming in Ice‐Covered Waters

Author

Damien Bouffard, Alfred Wüest, Kraig B. Winters, and Hugo N. Ulloa

Subjects

Convection, Geophysics, Circulation (fluid dynamics), Mixed layer, General Earth and Planetary Sciences, Environmental science, Lake ice, Differential heating, Atmospheric sciences

Published

2019

25. MODIS-observed variations of lake ice phenology in Xinjiang, China

Author

Chang-Qing Ke, Xiaoyi Shen, Guohui Yao, and Yu Cai

Subjects

Atmospheric Science, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Phenology, 0208 environmental biotechnology, Climate change, 02 engineering and technology, Snow, 01 natural sciences, Arid, 020801 environmental engineering, Environmental science, Lake ice, Precipitation, Physical geography, Moderate-resolution imaging spectroradiometer, China, 0105 earth and related environmental sciences

Abstract

Lakes sensitively respond to global and regional climate change, especially in arid areas. Using Moderate Resolution Imaging Spectroradiometer (MODIS) daily snow products, the lake ice phenology of 23 lakes in the Xinjiang Uygur Autonomous Region of China from 2001 to 2018 was extracted based on thresholds of ice/water pixel numbers, and their change trends over 18 years were calculated. The results of MODIS-derived lake ice phenology showed consistent variations with existing ice phenology data sets derived from passive microwave data. Generally, lakes in Xinjiang begin to freeze from October to December every year, and their ice cover periods end from March to June. The average ice cover duration for the 23 lakes is 167 days, of which 16 lakes have an average shortening rate of − 1.08 days/year and seven lakes have an average extending rate of 1.18 days/year. The majority of lakes experienced later freeze-up (17 lakes) and earlier break-up (18 lakes) from 2001 to 2018. Lake ice phenology is affected by both climatic factors and lake physicochemical characteristics, in which freeze-up dates are more easily affected by lake-specific factors such as lake area (r = 0.535), while climatic factors especially water surface temperature have greater impacts on lake break-up dates (r = − 0.874). Compared to air temperature, water surface temperature changes have a more direct influence on the variations in lake ice phenology, 1° increase in water surface temperature may cause the ice cover duration to decrease by 12 days, while precipitation changes have almost no effect on the lakes in Xinjiang. In some cases, lake changes such as changes to the area and mineralization may also have dominant impacts on lake ice phenology.

Published

2019

26. Lake Ontario ice coverage: Past, present and future

Author

William A. Gough and Micah J. Hewer

Subjects

0106 biological sciences, Ecology, 010604 marine biology & hydrobiology, Metric (mathematics), Lake ice, Environmental science, Physical geography, 010501 environmental sciences, Aquatic Science, 01 natural sciences, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Lake Ontario ice conditions are statistically linked to regional temperatures recorded in Toronto, during the most recent climate normal (1980/81–2009/10). A metric was developed to capture the net melting effect of average winter temperatures to characterize lake ice conditions, referred to as Net Melting-Degree Days (NMDD). This metric was able to account for 78% of lake ice interannual variability (R2 = 0.783, P

Published

2019

27. Modeling present and future ice covers in two Antarctic lakes

Author

Nicolas Bambach, Sebastian Echeverria, Sebastián Vicuña, Francisco Suárez, and Mark B. Hausner

Subjects

010504 meteorology & atmospheric sciences, Turbulent heat, Ephemeral key, 0208 environmental biotechnology, Climate change, 02 engineering and technology, Atmospheric sciences, 01 natural sciences, 020801 environmental engineering, Water body, Radiative transfer, Lake ice, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Antarctic lakes with perennial ice covers provide the opportunity to investigate in-lake processes without direct atmospheric interaction, and to study their ice-cover sensitivity to climate conditions. In this study, a numerical model – driven by radiative, atmospheric and turbulent heat fluxes from the water body beneath the ice cover – was implemented to investigate the impact of climate change on the ice covers from two Antarctic lakes: west lobe of Lake Bonney (WLB) and Crooked Lake. Model results agreed well with measured ice thicknesses of both lakes (WLB – RMSE= 0.11 m over 16 years of data; Crooked Lake – RMSE= 0.07 m over 1 year of data), and had acceptable results with measured ablation data at WLB (RMSE= 0.28 m over 6 years). The differences between measured and modeled ablation occurred because the model does not consider interannual variability of the ice optical properties and seasonal changes of the lake's thermal structure. Results indicate that projected summer air temperatures will increase the ice-cover annual melting in WLB by 2050, but that the ice cover will remain perennial through the end of this century. Contrarily, at Crooked Lake the ice cover becomes ephemeral most likely due to the increase in air temperatures.

Published

2019

28. Mapping of Bottomfast Lake Ice in the Northwest Territories Via Data Mining of Synthetic Aperture Radar Image Time Series

Author

M. Chiang, A. Dean, and Olivier W. Tsui

Subjects

Series (stratigraphy), Surface water resources, Satellite remote sensing, Synthetic aperture radar image, General Earth and Planetary Sciences, Lake ice, Precipitation, Geology, Remote sensing

Abstract

Changes in climate, warming temperatures and increased precipitation are impacting surface water resources in the Northwest Territories, Canada. Satellite remote sensing is an important tool to mon...

Published

2019

29. Coupling of a physically based lake model into the climate forecast system to improve winter climate forecasts for the Great Lakes region

Author

Shaobo Zhang, Zhemin Lv, Yihua Wu, Michael Ek, and Jiming Jin

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Land use, Mesoscale meteorology, 010502 geochemistry & geophysics, 01 natural sciences, Atmosphere, Flux (metallurgy), Hydrology (agriculture), Climatology, Climate Forecast System, Lake ice, Environmental science, Precipitation, 0105 earth and related environmental sciences

Abstract

In this study, we coupled the two-layer one-dimensional Freshwater lake (FLake) model into the Climate Forecast System (CFS) version 2 to improve simulations of the effects of the Great Lakes on winter climate forecasts in that region. We first incorporated global lake fraction and depth data into the coupled CFS-FLake through a subgridding system. An interface between the CFS and FLake was then developed to link the two models for energy and water flux exchanges. The lake scheme was triggered only if the lake fraction was more than 10% in one CFS grid cell. We conducted ensemble retrospective forecasts with CFS-FLake for the period of 1997 through 2016 with 9 monthly leads. These forecasts were assessed to obtain a better understanding of the role of the Great Lakes in the climate system for winter, when significant lake-effect precipitation often occurs. Our results indicate that forecasts of lake surface temperature (LST), lake ice coverage (LIC), and precipitation with CFS-FLake were consistently better than those with CFS. The major improvements resulted from changes in land use type for the Great Lakes, from ocean and land in CFS to lakes in CFS-FLake. With the change from ocean to lake, LST mostly decreased with increasing LIC, resulting in lower surface heat and water fluxes to the atmosphere during the winter. However, with the change from land to lake, LST increased, leading to higher heat and water fluxes. In the meantime, precipitation predicted by CFS-FLake was reduced quite significantly over the Great Lakes compared to that by CFS. This reduction was caused by suppressed rising motion due to increased stability in the lower atmosphere as a result of lowered surface heat and water fluxes. The results from this study indicate that local and mesoscale surface and atmospheric processes significantly affect regional climate forecasts, and the coupled CFS-FLake model will have a broader impact on climate and hydrology research and forecasts.

Published

2019

30. MODIS-based Daily Lake Ice Extent and Coverage dataset for Tibetan Plateau

Author

Yubao Qiu, Pengfei Xie, Matti Leppäranta, Lijuan Shi, Juha Lemmetyinen, Xingxing Wang, Hui Lin, and Institute for Atmospheric and Earth System Research (INAR)

Subjects

1171 Geosciences, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, Daily, 02 engineering and technology, 01 natural sciences, Tibetan Plateau, Computers in Earth Sciences, Duration (project management), 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, geography, Plateau, geography.geographical_feature_category, Lake Ice Extent, Phenology, lcsh:QE1-996.5, Global warming, lcsh:Geography. Anthropology. Recreation, Computer Science Applications, lcsh:Geology, MODIS, lcsh:G, 13. Climate action, Environmental science, Lake ice, Lake Ice Coverage, Physical geography

Abstract

The Tibetan Plateau houses numerous lakes, the phenology and duration of lake ice in this region are sensitive to regional and global climate change, and as such are used as key indicators in climate change research, particularly in environment change comparison studies for the Earth three poles. However, due to its harsh natural environment and sparse population, there is a lack of conventional in situ measurement on lake ice phenology. The Moderate Resolution Imaging Spectroradiometer (MODIS) Normalized Difference Snow Index (NDSI) data, which can be traced back 20 years with a 500 m spatial resolution, were used to monitor lake ice for filling the observation gaps. Daily lake ice extent and coverage under clear-sky conditions was examined by employing the conventional SNOWMAP algorithm, and those under cloud cover conditions were re-determined using the temporal and spatial continuity of lake surface conditions through a series of steps. Through time series analysis of every single lake with size greater than 3 km2 in size, 308 lakes within the Tibetan Plateau were identified as the effective records of lake ice extent and coverage to form the Daily Lake Ice Extent and Coverage dataset, including 216 lakes that can be further retrieved with four determinable lake ice parameters: Freeze-up Start (FUS), Freeze-up End (FUE), Break-up Start (BUS), and Break-up End (BUE), and 92 lakes with two parameters, FUS and BUE. Six lakes of different sizes and locations were selected for verification against the published datasets by passive microwave remote sensing. The lake ice phenology information obtained in this paper was highly consistent with that from passive microwave data at an average correlation coefficient of 0.91 and an RMSE value varying from 0.07 to 0.13. The present dataset is more effective at detecting lake ice parameters for smaller lakes than the coarse resolution passive microwave remote sensing observations. The published data are available in https://data.4tu.nl/repository/uuid:fdfd8c76-6b7c-4bbf-aec8-98ab199d9093 and http://www.sciencedb.cn/dataSet/handle/744.

Published

2019

31. Evaluation of Low-Cost, Automated Lake Ice Thickness Measurements

Author

David E. Reed, Emily C. Whitaker, Henry Nuckles, and Ankur R. Desai

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Middle latitudes, Lake ice, Ocean Engineering, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Geology, 0105 earth and related environmental sciences, Ice thickness

Abstract

Climate change is expected to decrease ice coverage and thickness globally while increasing the variability of ice coverage and thickness on midlatitude lakes. Ice thickness affects physical, biological, and chemical processes as well as safety conditions for scientists and the general public. Measurements of ice thickness that are both temporally frequent and spatially extensive remain a technical challenge. Here new observational methods using repurposed soil moisture sensors that facilitate high spatial–temporal sampling of ice thickness are field tested on Lake Mendota in Wisconsin during the winter 2015/16 season. Spatial variability in ice thickness was high, with differences of 10 cm of ice column thickness over 1.05 km of horizontal distance. When observational data were compared with manual measurements and model output from both the Freshwater Lake (FLake) model and General Lake Model (GLM), ice thickness from sensors matches manual measurements, whereas GLM and FLake results showed a thinner and thicker ice layer, respectively. The FLake-modeled ice column temperature effectively remained at 0°C, not matching observations. We also show that daily ice dynamics follows the expected linear function of ice thickness growth/melt, improving confidence in sensor accuracy under field conditions. We have demonstrated a new method that allows low-cost and high-frequency measurements of ice thickness, which will be needed both to advance winter limnology and to improve on-ice safety.

Published

2019

32. Synoptic climate evidence of a late-twentieth century change to earlier spring ice-out on Maine Lakes, USA

Author

Andrew W. Ellis and Timothy R. Greene

Subjects

Atmospheric Science, Global and Planetary Change, Trend analysis, La Niña, Geography, geography.geographical_feature_category, Phenology, Climatology, Spring (hydrology), Period (geology), Lake ice, Precipitation, Teleconnection

Abstract

Trend analysis of spring ice-out on eight lakes within the state of Maine of the northeastern USA reveals a change to earlier occurrence by 1 to 2 weeks over the period 1956–2015. Much of the trend occurred from the late 1970s through the 1980s, but a secondary trend toward earlier ice-out appears to have begun in the late 1990s. Synoptic climate data support local and hemispheric climate evidence of increasingly earlier ice-out, particularly during the earlier period of pronounced change. Local spring and winter maximum daily air temperatures increased while winter precipitation decreased; synoptic weather types of moderate temperature character increased in frequency, while polar types became less frequent; synoptic weather types became warmer in spring and winter, and in spring, warmer weather types became wetter, while cooler weather types became drier; and two key climate teleconnections, the Pacific-North American pattern and the El Nino/La Nina pattern, changed significantly toward a phase historically associated with earlier ice-out. While the results underscore the value in monitoring and study of lake ice as a climate proxy, they also demonstrate the value of synoptic climate data for filling the spatial gap between local and large-scale climate data in studies of lake ice phenology.

Published

2019

33. Recent trends of ice phenology for eight large lakes using MODIS products in Northeast China

Author

Zhidan Wen, Chong Fang, Kaishan Song, Qian Yang, and Xiaohua Hao

Subjects

Remote sensing (archaeology), Phenology, Climatology, General Earth and Planetary Sciences, Environmental science, High temporal resolution, Lake ice

Abstract

Optical remote sensing images with high temporal resolution can be used to monitor lake ice phenology, a periodic freezing and thawing cycle of ice resulting from seasonal and inter-annual climate ...

Published

2019

34. Prediction of Ice‐Free Conditions for a Perennially Ice‐Covered Antarctic Lake

Author

Maciej K. Obryk, John C. Priscu, and Peter T. Doran

Subjects

Geophysics, Oceanography, Limnology, Lake ice, Cryosphere, Geology, Earth-Surface Processes

Published

2019

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

Author

John J. Magnuson, Samantha K. Oliver, Gesa A. Weyhenmeyer, Dietmar Straile, Catherine M. O'Reilly, Luke A. Winslow, Sapna Sharma, Kevin Blagrave, R. Iestyn Woolway, Ryan D. Batt, and Madeline R. Magee

Subjects

Shore, 0303 health sciences, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Range (biology), Phenology, Elevation, Northern Hemisphere, Environmental Science (miscellaneous), 01 natural sciences, Ecosystem services, 03 medical and health sciences, Environmental science, Lake ice, Ecosystem, Physical geography, Social Sciences (miscellaneous), 030304 developmental biology, 0105 earth and related environmental sciences

Abstract

Ice provides a range of ecosystem services—including fish harvest1, cultural traditions2, transportation3, recreation4 and regulation of the hydrological cycle5—to more than half of the world’s 117 million lakes. One of the earliest observed impacts of climatic warming has been the loss of freshwater ice6, with corresponding climatic and ecological consequences7. However, while trends in ice cover phenology have been widely documented2,6,8,9, a comprehensive large-scale assessment of lake ice loss is absent. Here, using observations from 513 lakes around the Northern Hemisphere, we identify lakes vulnerable to ice-free winters. Our analyses reveal the importance of air temperature, lake depth, elevation and shoreline complexity in governing ice cover. We estimate that 14,800 lakes currently experience intermittent winter ice cover, increasing to 35,300 and 230,400 at 2 and 8 °C, respectively, and impacting up to 394 and 656 million people. Our study illustrates that an extensive loss of lake ice will occur within the next generation, stressing the importance of climate mitigation strategies to preserve ecosystem structure and function, as well as local winter cultural heritage. Up to 35,000 lakes in the Northern Hemisphere may be at risk of intermittent winter ice cover at 2 °C warming, reveals an observation-based study. This would affect 394 million people reliant on lake ice for ecosystem services.

Published

2019

36. Spatiotemporal characteristics of Qinghai Lake ice phenology between 2000 and 2016

Author

Hongyu Duan, Miao-miao Qi, Xiaojun Yao, Yongpeng Gao, Juan Liu, and Xiaofeng Li

Subjects

geography, Series (stratigraphy), Plateau, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Phenology, 05 social sciences, 0507 social and economic geography, Climate change, 01 natural sciences, Earth and Planetary Sciences (miscellaneous), Spatial ecology, Environmental science, Lake ice, Physical geography, Precipitation, Qinghai lake, 050703 geography, 0105 earth and related environmental sciences

Abstract

Lake ice phenology is considered a sensitive indicator of regional climate change. We utilized time series information of this kind extracted from a series of multi-source remote sensing (RS) datasets including the MOD09GQ surface reflectance product, Landsat TM/ETM+ images, and meteorological records to analyze spatiotemporal variations of ice phenology of Qinghai Lake between 2000 and 2016 applying both RS and GIS technology. We also identified the climatic factors that have influenced lake ice phenology over time and draw a number of conclusions. First, data show that freeze-up start (FUS), freeze-up end (FUE), break-up start (BUS), and break-up end (BUE) on Qinghai Lake usually occurred in mid-December, early January, mid-to-late March, and early April, respectively. The average freezing duration (FD, between FUE and BUE), complete freezing duration (CFD, between FUE and BUS), ice coverage duration (ICD, between FUS and BUE), and ablation duration (AD, between BUS and BUE) were 88 days, 77 days, 108 days and 10 days, respectively. Second, while the results of this analysis reveal considerable differences in ice phenology on Qinghai Lake between 2000 and 2016, there has been relatively little variation in FUS times. Data show that FUE dates had also tended to fluctuate over time, initially advancing and then being delayed, while the opposite was the case for BUS dates as these advanced between 2012 and 2016. Overall, there was a shortening trend of Qinghai Lake’s FD in two periods, 2000–2005 and 2010–2016, which was shorter than those seen on other lakes within the hinterland of the Tibetan Plateau. Third, Qinghai Lake can be characterized by similar spatial patterns in both freeze-up (FU) and break-up (BU) processes, as parts of the surface which freeze earlier also start to melt first, distinctly different from some other lakes on the Tibetan Plateau. A further feature of Qinghai Lake ice phenology is that FU duration (between 18 days and 31 days) is about 10 days longer than BU duration (between 7 days and 20 days). Fourth, data show that negative temperature accumulated during the winter half year (between October and the following April) also plays a dominant role in ice phenology variations of Qinghai Lake. Precipitation and wind speed both also exert direct influences on the formation and melting of lake ice cover and also cannot be neglected.

Published

2019

37. Comparison of Lake Ice Extraction Methods Based on MODIS Images

Author

Hongfang Zhang, Xiaojun Yao, Qixin Wei, Hongyu Duan, and Yuan Zhang

Subjects

lake ice, phenology, MODIS, Qinghai Lake, Qinghai–Tibet Plateau, General Earth and Planetary Sciences

Abstract

As an important part of the cryosphere, lake ice is a sensitive indicator of climate change. Remote sensing technology can quickly and accurately monitor the process of its formation and decay, among which Moderate Resolution Imaging Spectroradiometer (MODIS) images are the most widely used data in the remote sensing monitoring of lake ice. The reasonable selection of monitoring methods is of great significance to grasp the dynamic process and response to climate change of lake ice. In this study, five commonly used remote sensing monitoring methods of lake ice based on MODIS MOD09GA data, including the single band threshold method (SBT), reflectance difference threshold method (RDT), normalized difference snow index method (NDSI), modified normalized difference snow index method (MNDSI) and lake ice index method (LII), were selected to compare their accuracies in extracting lake ice extent by combining them with four evaluation metrics of accuracy, precision, recall and mean intersection over union (MIoU). In addition, the ability of the high-precision LII method for extracting long time series lake ice phenology and its applicability to multiple types of lakes were verified. The results showed that compared with the NDSI method, the other four methods more easily distinguished between lake ice and lake water by setting thresholds. The SBT method and the RDT method had better extraction effects in the freezing process and the melting process, respectively. Compared with the NDSI and MNDSI methods, the LII method showed a significant improvement in lake ice extraction over the entire freeze–thaw cycle, with the smallest mean monitoring error of 1.53% for the percentage of lake ice area in different periods. Meanwhile, the LII method can be used to determine long term lake ice phenology dates and had good performance in extracting lake ice for different types of lakes on the Qinghai–Tibet Plateau with the optimal threshold interval of 0.05~0.07, which can be used for lake ice monitoring and long-term phenological studies in this region.

Published

2022

38. Simulating Landfast Ice in Lake Superior

Author

Yuchun Lin, Ayumi Fujisaki-Manome, and Eric J. Anderson

Subjects

Ocean Engineering, landfast ice, basal stress, numerical simulation, Great Lakes, lake ice, ice modeling, Water Science and Technology, Civil and Structural Engineering

Abstract

Landfast ice plays an important role in the nearshore hydrodynamics of large lakes, such as the dampening of surface waves and currents. In this study, previously developed landfast ice basal stress parameterizations were added to an unstructured grid hydrodynamic ice model to represent the effects of grounded ice keels and tensile strength of ice cover. Numerical experiments using this model were conducted to evaluate the development of coastal landfast ice in Lake Superior. A sensitivity study of the free parameters was conducted from December 2018 to May 2021 to cover both high and low ice cover winters in Lake Superior and was compared against observations from the United States National Ice Center. The model reproduces the annual variation in coastal landfast ice in Lake Superior, particularly in shallow nearshore areas and the semi-enclosed bays in the northern regions of the lake. Experiments also show that the growth of landfast ice is mainly controlled by the free parameter that controls the critical ice thickness for the activation of basal stress. Overall, the model tends to underestimate the extent of coastal landfast against observations.

Published

2022

39. A Comparison of Ecological Memory of Lake Ice‐Off in Eight North‐Temperate Lakes

Author

Hilary A. Dugan

Subjects

Atmospheric Science, Ecology, Limnology, Lake ecosystem, Temperate climate, Paleontology, Soil Science, Lake ice, Environmental science, Forestry, Aquatic Science, Water Science and Technology

Published

2021

40. Lake ice phenology changes in the northern hemisphere

Author

Xingxing Wang, Yixiao Zhang, Bin Cheng, Yubao Qiu, and Matti Leppäranta

Subjects

Phenology, Northern Hemisphere, Lake ice, Physical geography, Geology

Abstract

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 (Crétaux et al., 2020).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°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.

Published

2021

41. The potential of using Sentinel-1 and ALOS PALSAR-2 data for characterizing West Siberian lake ice backscatter anomalies

Author

Georg Pointner and Annett Bartsch

Subjects

Backscatter, Climatology, Lake ice, Geology

Abstract

Millions of lakes and ponds occupy large areas of the Arctic discontinuous and continuous permafrost zones. During most of the year, the surfaces of these lakes remain covered by a thick layer of ice. Synthetic Aperture Radar (SAR) data have shown to be useful for studying the ice on Arctic lakes, especially for monitoring lake ice phenology and the grounding state of the ice (ice frozen to the lakebed versus floating lake ice). Significant backscatter is often observed from the floating ice regime in C-band due to scattering on a rough ice-water interface.Recent research has revealed features of anomalously low backscatter in Sentinel-1 C-band SAR imagery on some of the West Siberian lakes that likely belong to the floating ice regime. These anomalies are characterized by prominent shapes and sizes and seem to expand throughout late winter and/or spring. It is currently assumed that some of these features are related to strong emissions of natural gas (methane from hydrocarbon reservoirs), making it important to assess their origin in detail and understand the associated mechanisms. However, in-situ data are still missing.Here, we assess the potential of the combined use of C-band Sentinel-1 (freely available) and L-band ALOS PALSAR-2 data (available through JAXA PI agreement #3068002) to study the backscatter anomalies. We highlight the differences between observed backscatter from the two sensors with respect to different surface types (ground-fast lake ice, floating lake ice and anomalies) and investigate backscatter differences between frozen and melting conditions. Further, polarimetric classification is performed on L-band PALSAR-2 imagery, which reveals differences in scattering mechanisms between anomalies and floating lake ice.

Published

2021

42. The Role of Climate and Lake Size in Regulating the Ice Phenology of Boreal Lakes

Author

Lee E. Hrenchuk, J.J. van der Sanden, C. M. Desjardins, Scott N. Higgins, and H. Drouin

Subjects

Atmospheric Science, Ecology, Regional variation, Phenology, Paleontology, Soil Science, Environmental science, Lake ice, Forestry, Physical geography, Aquatic Science, Water Science and Technology, Boreal lakes

Published

2021

43. Forecasting the Permanent Loss of Lake Ice in the Northern Hemisphere Within the 21st Century

Author

M. Arshad Imrit, Alessandro Filazzola, Harrie-Jan Hendricks Franssen, Sapna Sharma, and Kevin Blagrave

Subjects

Geophysics, ddc:550, Northern Hemisphere, General Earth and Planetary Sciences, Lake ice, Physical geography, Geology

Abstract

Lake ice cover is essential to conserving the global freshwater supply for the 50 million lakesthat freeze each winter. Here, we ask when lakes across the Northern Hemisphere may permanently loseice cover. A K-means cluster analysis from 31 lakes identified four clusters of lakes vulnerable to losing icecover, including shallow and deep lakes in regions where winter air temperatures hover ∼0 °C and largerand deeper lakes in colder regions. By the end of this century, we estimate that up to 5,679 lakes of 1.35million HydroLAKES may permanently lose ice cover if greenhouse gas emissions (GHG) continue tobe emitted at current levels. In the Northern Hemisphere, lakes in southern and coastal regions, some ofwhich are among the largest lakes in the world and in close proximity to large human populations, are themost vulnerable to permanently losing ice.

Published

2021

44. Seeing the Invisible Present and Place: From Years to Centuries with Lake Ice from Wisconsin to the Northern Hemisphere

Author

John J. Magnuson

Subjects

Geography, North Atlantic oscillation, Phenology, Limnology, Northern Hemisphere, Temperate climate, medicine, Lake ice, Climate change, Physical geography, Seasonality, medicine.disease

Abstract

Ecologists involved in long-term research created the metaphors of the “Invisible Present” and the “Invisible Place” to communicate the purposes of Long-Term Ecological Research to the National Science Foundation, other scientists, and the wider public. This chapter discusses using lake ice cover to tackle the joint problems of the Invisible Present and the Invisible Place, by expanding the time and space scales not only at the North Temperate Lakes Long-Term Ecological Research site, but across Wisconsin, North America, and the Northern Hemisphere. LTER formed an international Lake Ice Analysis Group in the mid-1990s, to create and make publicly available a common lake ice phenology database. By 2000, analyses of ice cover provided strong evidence for warming winters in the Northern Hemisphere, and for the impact of the Second Industrial Revolution on climate. Importantly, for ice freeze time series, 20 and 50 years of data were insufficient to detect climate change while longer records did; large-scale climate drivers like El Nino, the North Atlantic Oscillation, as well as local weather influenced inter-year dynamics of lake ice seasonality; inter-year dynamics between lakes were coherent locally and persisted regionally at lower values; extreme ice dates changed in the direction of a warming climate; and changes in lake ice already have affected people negatively. Research on inland water ice and winter limnology continues today and has depended on successes in continuing leadership and participation within and beyond the LTER program.

Published

2021

45. Classification and Geographical Distribution of Cryosphere

Author

Jiawen Ren, Yongjian Ding, Tandong Yao, and Dahe Qin

Subjects

geography, geography.geographical_feature_category, business.industry, Distribution (economics), Glacier, Atmosphere, Sea ice, Cryosphere, Lake ice, Physical geography, Ice sheet, Scale (map), business, Geology

Abstract

This chapter describes the classification of the cryospheric components and their geographical distribution in the world. The first part introduces the overall distribution of the continental cryosphere, marine cryosphere and aerial cryosphere on the global scale, followed by the classification and geographical distribution of glaciers and ice sheets, frozen ground, snow cover, sea ice, river and lake ice, and all solid water in the atmosphere. The geographical distribution of a single cryospheric component is introduced at the global scale, then at the hemispheric scale and finally at the national scale.

Published

2021

46. Behavior of Saline Ice under Cyclic Flexural Loading

Author

A. Murdza, E. M. Schulson, and C. E. Renshaw

Subjects

QE1-996.5, Materials science, 010504 meteorology & atmospheric sciences, medicine.medical_treatment, 0211 other engineering and technologies, Geology, 02 engineering and technology, 01 natural sciences, Environmental sciences, Salinity, Brine, Flexural strength, Acoustic emission, medicine, Lake ice, Cyclic loading, GE1-350, Composite material, Cycling, Saline, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

New systematic experiments reveal that the flexural strength of saline S2 columnar-grained ice loaded normal to the columns can be increased upon cyclic loading by about a factor of 1.5. The experiments were conducted using reversed cyclic loading over ranges of frequencies from 0.1 to 0.6 Hz and at a temperature of −10 ∘C on saline ice of two salinities: 3.0 ± 0.9 and 5.9 ± 0.6 ‰. Acoustic emission hit rate during cycling increases with an increase in stress amplitude of cycling. Flexural strength of saline ice of 3.0 ± 0.9 ‰ salinity appears to increase linearly with increasing stress amplitude, similar to the behavior of laboratory-grown freshwater ice (Murdza et al., 2020b) and to the behavior of lake ice (Murdza et al., 2021). The flexural strength of saline ice of 5.9 ± 0.6 ‰ depends on the vertical location of the sample within the thickness of an ice puck; i.e., the strength of the upper layers, which have a lower brine content, was found to be as high as 3 times that of lower layers. The fatigue life of saline ice is erratic. Cyclic strengthening is attributed to the development of an internal back stress that opposes the applied stress and possibly originates from dislocation pileups.

Published

2020

47. Prediction and Analysis of Lake Ice Phenology Dynamics Under Future Climate Scenarios Across the Inner Tibetan Plateau

Author

Qinchuan Xin, Yubao Qiu, Ying Sun, Yongjian Ruan, and Xinchang Zhang

Subjects

Atmospheric Science, geography, Geophysics, Plateau, geography.geographical_feature_category, Space and Planetary Science, Phenology, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science, Climate change, Lake ice, Future climate

Published

2020

48. Phenology of alpine zooplankton populations and the importance of lake ice-out

Author

Kyle R. Christianson, Kelly A. Loria, and Pieter T. J. Johnson

Subjects

0106 biological sciences, Oceanography, 010504 meteorology & atmospheric sciences, Ecology, Phenology, 010604 marine biology & hydrobiology, Environmental science, Lake ice, Aquatic Science, 01 natural sciences, Zooplankton, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

The prolonged ice cover inherent to alpine lakes incurs unique challenges for aquatic life, which are compounded by recent shifts in the timing and duration of ice cover. To understand the responses of alpine zooplankton, we analyzed a decade (2009–2019) of open-water samples of Daphnia pulicaria and Hesperodiaptomus shoshone for growth, reproduction and ultraviolet radiation tolerance. Due to reproductive differences between taxa, we expected clonal cladocerans to exhibit a more rapid response to ice-cover changes relative to copepods dependent on sexual reproduction. For D. pulicaria, biomass and melanization were lowest after ice clearance and increased through summer, whereas fecundity was highest shortly after ice-off. For H. shoshone, biomass and fecundity peaked later but were generally less variable through time. Among years, ice clearance date varied by 49 days; years with earlier ice-out and a longer growing season supported higher D. pulicaria biomass and clutch sizes along with greater H. shoshone fecundity. While these large-bodied, stress tolerant zooplankton taxa were relatively resilient to phenological shifts during the observation period, continued losses of ice cover may create unfavorably warm conditions and facilitate invasion by montane species, emphasizing the value of long-term data in assessing future changes to these sensitive ecosystems.

Published

2020

49. Climate Change Drives Increases in Extreme Events for Lake Ice in the Northern Hemisphere

Author

Mohammad Arshad Imrit, Alessandro Filazzola, Sapna Sharma, and Kevin Blagrave

Subjects

0106 biological sciences, Geophysics, 010504 meteorology & atmospheric sciences, 010604 marine biology & hydrobiology, Climatology, Northern Hemisphere, Extreme events, General Earth and Planetary Sciences, Climate change, Environmental science, Lake ice, 01 natural sciences, 0105 earth and related environmental sciences

Published

2020

50. Lake Ice—and Ecosystems—in a Warming World

Author

Terri Cook

Subjects

Oceanography, General Earth and Planetary Sciences, Lake ice, Environmental science, Ecosystem

Abstract

Extending ice records and standardizing sampling protocols are among recommendations to help researchers better predict how changing ice cover will affect aquatic ecosystems.

Published

2020