4.5 Article

Functional Lake-to-Channel Connectivity Impacts Lake Ice in the Colville Delta, Alaska

Journal

Publisher

AMER GEOPHYSICAL UNION
DOI: 10.1029/2021JF006362

Keywords

Arctic deltas; lake connectivity; lake ice; remote sensing of water color

Funding

  1. NASA FINESST [80NSSC19K1344]
  2. UNC Preston Jones and Mary Elizabeth Frances Dean Martin Fellowship Fund

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This study developed a method based on satellite observations to detect lake connectivity variations in the Arctic Colville River Delta. Most lakes remain connected or disconnected, but about 10% show variable connectivity, with higher connectivity during periods of high river discharge. Changes in connectivity affect lake ice phenology and are important when studying the biogeochemistry of Arctic delta lakes.
Within Arctic deltas, surficial hydrologic connectivity of lakes to nearby river channels influences physical processes like sediment transport and ice phenology as well as biogeochemical processes such as photochemistry. As the Arctic hydrologic cycle is impacted by climate change, it is important to quantify temporal variability in connectivity. However, current connectivity detection methods are either spatially limited due to data availability constraints or have been applied at only a single time. Additionally, the relationship between connectivity and lake ice is still poorly quantified. In this study, we present a multitemporal classification of functional lake connectivity in the Colville River Delta, Alaska. We introduce a connectivity detection algorithm based on remote sensing of high sediment river water recharge that is expandable to other high sediment Arctic deltas. We compare results to three existing data sets, producing 64.4%, 75.8%, and 85.2% lake classification accuracy. Mismatches between the data sets are often due to inconsistencies in methodology or definition of connectivity. Connectivity varies temporally in about 10% of studied lakes and correlates strongly with discharge and lake elevation, supporting the idea that future changes in discharge will be a driver of changes in connectivity. Highly connected lakes start and end ice break up an average of 26 and 17 days earlier, respectively, compared to lakes that are poorly connected. Because spring and summer ice conditions drive Arctic lake photochemistry processes, our research suggests that surface connectivity is an important parameter to consider when studying biogeochemistry of Arctic delta lakes. Plain Language Summary Arctic deltas contain a complex tapestry of channels and lakes. Lakes can be isolated from channels or connected to channels-either by feeder channels, other lakes, or by water movement over land during flooding. This connectivity is important because it impacts the movement of sediment, light penetration through water, and when lake ice forms and disappears. While we anticipate future changes in connectivity due to climate change, our ability to monitor connectivity is limited to individual deltas or single instances in time. Additionally, the relationship between lake ice and connectivity is poorly understood. In this study, we used a method based on satellite observations of sediment in water to examine lake connectivity variations within the Colville River Delta, Alaska. We found that most lakes stay connected or disconnected, but that about 10% of lakes have variable connectivity. These lakes are more likely to be connected when river discharge is high. Additionally, lake ice tends to break up earlier and last for a shorter period of time in connected lakes. Because lake ice conditions drive chemical interaction between sunlight and organic compounds in the water, connectivity is important to consider when studying the biology and chemistry of Arctic delta lakes. Key Points We have developed an algorithm using optical properties of lakes and channels to detect lake-to-channel connectivity in an Arctic delta We show that this algorithm can be used to detect lakes where functional connectivity varies based on maximum summer discharge Differences in functional connectivity drive lake ice phenology, which is likely important for photochemical processes

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