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1. Lake and drained lake basin systems in lowland permafrost regions

   https://doi.org/10.1038/s43017-021-00238-9  

   Jones, Benjamin M.; Grosse, Guido; Farquharson, Louise M.; Roy-Léveillée, Pascale; Veremeeva, Alexandra; Kanevskiy, Mikhail Z.; Gaglioti, Benjamin V.; Breen, Amy L.; Parsekian, Andrew D.; Ulrich, Mathias; et al (January 2022, Nature Reviews Earth & Environment)
2. Water properties of Arco Lake, Budd Lake, Deming Lake, and Josephine Lake in Itasca State Park from 2006-2009 and 2019-2023.

   https://doi.org/10.6073/pasta/eb8757dedf22ce40e79ca410c2ab9a34  

   Swanner, Elizabeth D; Lascu, Ioan; Harding, Chris; Ledesma, Gabrielle; Leung, Tania; Akam, Sajjad; Chamberlain, Michelle; Ostrander, Chadlin; Heard, Andrew (January 2023, Environmental Data Initiative)

   Depth profiles of water column chemical and physical properties were assessed with seasonal-scale frequency from four lakes in the Itasca State Park from 2006-2009 and from 2019-2023. The data was used to assess the mixing status and major geochemical constituents within the lakes. Several parameters were routinely measured with deployable probes at meter or sub-meter resolution at the deepest location in each lake. Water samples were also collected for laboratory analysis. Bathymetry data collected in 2022 is supplied as rasters. 

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3. Periglacial Lake Origin Influences the Likelihood of Lake Drainage in Northern Alaska

   https://doi.org/10.3390/rs13050852  

   Lara, Mark Jason; Chipman, Melissa Lynn (March 2021, Remote Sensing)

   Nearly 25% of all lakes on earth are located at high latitudes. These lakes are formed by a combination of thermokarst, glacial, and geological processes. Evidence suggests that the origin of periglacial lake formation may be an important factor controlling the likelihood of lakes to drain. However, geospatial data regarding the spatial distribution of these dominant Arctic and subarctic lakes are limited or do not exist. Here, we use lake-specific morphological properties using the Arctic Digital Elevation Model (DEM) and Landsat imagery to develop a Thermokarst lake Settlement Index (TSI), which was used in combination with available geospatial datasets of glacier history and yedoma permafrost extent to classify Arctic and subarctic lakes into Thermokarst (non-yedoma), Yedoma, Glacial, and Maar lakes, respectively. This lake origin dataset was used to evaluate the influence of lake origin on drainage between 1985 and 2019 in northern Alaska. The lake origin map and lake drainage datasets were synthesized using five-year seamless Landsat ETM+ and OLI image composites. Nearly 35,000 lakes and their properties were characterized from Landsat mosaics using an object-based image analysis. Results indicate that the pattern of lake drainage varied by lake origin, and the proportion of lakes that completely drained (i.e., >60% area loss) between 1985 and 2019 in Thermokarst (non-yedoma), Yedoma, Glacial, and Maar lakes were 12.1, 9.5, 8.7, and 0.0%, respectively. The lakes most vulnerable to draining were small thermokarst (non-yedoma) lakes (12.7%) and large yedoma lakes (12.5%), while the most resilient were large and medium-sized glacial lakes (4.9 and 4.1%) and Maar lakes (0.0%). This analysis provides a simple remote sensing approach to estimate the spatial distribution of dominant lake origins across variable physiography and surficial geology, useful for discriminating between vulnerable versus resilient Arctic and subarctic lakes that are likely to change in warmer and wetter climates. 

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4. Insight Into the Molecular Mechanisms for Microcystin Biodegradation in Lake Erie and Lake Taihu

   https://doi.org/10.3389/fmicb.2019.02741  

   Krausfeldt, Lauren E.; Steffen, Morgan M.; McKay, Robert M.; Bullerjahn, George S.; Boyer, Gregory L.; Wilhelm, Steven W. (December 2019, Frontiers in Microbiology)
5. Lake-Effect Snowbands in Baroclinic Environments

   https://doi.org/10.1175/WAF-D-18-0191.1  

   Eipper, Daniel T.; Greybush, Steven J.; Young, George S.; Saslo, Seth; Sikora, Todd D.; Clark, Richard D. (October 2019, Weather and Forecasting)

   Abstract Lake-effect snowstorms are often observed to manifest as dominant bands, commonly produce heavy localized snowfall, and may extend large distances inland, resulting in hazards and high societal impact. Some studies of dominant bands have documented concomitant environmental baroclinity (i.e., baroclinity occurring at a scale larger than the width of the parent lake), but the interaction of this baroclinity with the inland structure of dominant bands has been largely unexplored. In this study, the thermodynamic environment and thermodynamic and kinematic structure of simulated dominant bands are examined using WRF reanalyses at 3-km horizontal resolution and an innovative technique for selecting the most representative member from the WRF ensemble. Three reanalysis periods are selected from the Ontario Winter Lake-effect Systems (OWLeS) field campaign, encompassing 185 simulation hours, including 155 h in which dominant bands are identified. Environmental baroclinity is commonly observed during dominant-band periods and occurs in both the north–south and east–west directions. Sources of this baroclinity are identified and discussed. In addition, case studies are conducted for simulation hours featuring weak and strong along-band environmental baroclinity, resulting in weak and strong inland extent, respectively. These contrasting cases offer insight into one mechanism by which along-band environmental baroclinity can influence the inland structure and intensity of dominant bands: in the case with strong environmental baroclinity, inland portions of this band formed under weak instability and therefore exhibit slow overturning, enabling advection far inland under strong winds, whereas the nearshore portion forms under strong instability, and the enhanced overturning eventually leads to the demise of the inland portion of the band. 

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