Arctic-Boreal Lake Dynamics Revealed Using CubeSat Imagery

Fine-scale, subseasonal fluctuations in Arctic-Boreal surface water reflect regional water balance and modulate trace gas emissions to the atmosphere but have eluded detection using traditional satellite remote sensing. We use high-resolution (~3–5 m), high-frequency CubeSat sensors to measure near-...

Full description

Bibliographic Details
Main Authors: Cooley, S.W., Smith, L.C., Ryan, J.C., Pitcher, L.H., Pavelsky, T.M.
Format: Article in Journal/Newspaper
Language:English
Published: Blackwell Publishing Ltd 2019
Subjects:
remote sensing
CubeSats
machine learning
Arctic-Boreal lakes
arctic hydrology
Arctic
Boreal Lake
Canada
Scale Lake
Alaska
Online Access:https://doi.org/10.17615/66q3-1m44
https://cdr.lib.unc.edu/downloads/fj236b54k?file=thumbnail
https://cdr.lib.unc.edu/downloads/fj236b54k
Description
Summary:Fine-scale, subseasonal fluctuations in Arctic-Boreal surface water reflect regional water balance and modulate trace gas emissions to the atmosphere but have eluded detection using traditional satellite remote sensing. We use high-resolution (~3–5 m), high-frequency CubeSat sensors to measure near-daily changes in lake surface area through an object-based tracking method that incorporates machine learning to overcome notable limitations of CubeSat imagery. From ~76,000 images we obtain >2.2 million individual observations of changing surface areas for 85,358 lakes in Northern Canada and Alaska between 1 May and 1 October 2017. We find broad-scale lake area declines across diverse climatic, hydrologic, and physiographic terrains. Localized exceptions reveal lowland flooding and aquatic vegetation phenology cycles. Cumulative small shoreline changes of abundant lakes on the Canadian Shield exceed total inundation variations of better-studied lowland environments, revealing a surprisingly dynamic landscape with respect to subseasonal variations in surface water extent and trace gas emissions.

Similar Items