Canary in the coal mine: Historical oxygen decline in the Gulf of St. Lawrence due to large scale climate changes

Mariona Claret1, Eric D Galbraith2, Jaime B Palter2, Denis Gilbert3, Daniele Bianchi4 and John P Dunne5, (1)McGill University, Earth and Planetary Sciences, Montreal, QC, Canada, (2)McGill University, Montreal, QC, Canada, (3)Maurice Lamontagne Institute, Fisheries and Oceans Canada, Mont-Joli, QC, Canada, (4)University of California Los Angeles, Atmospheric and Oceanic Sciences, Los Angeles, CA, United States, (5)Geophysical Fluid Dynamics Laboratory, Princeton, NJ, United States
Abstract:
The regional signature of anthropogenic climate change on the atmosphere and upper ocean is often difficult to discern from observational timeseries, dominated as they are by decadal climate variability. Here we argue that a long-term decline of dissolved oxygen concentrations observed in the Gulf of S. Lawrence (GoSL) is consistent with anthropogenic climate change. Oxygen concentrations in the GoSL have declined markedly since 1930 due primarily to an increase of oxygen-poor North Atlantic Central Waters relative to Labrador Current Waters (Gilbert et al. 2005). We compare these observations to a climate warming simulation using a very high-resolution global coupled ocean-atmospheric climate model. The numerical model (CM2.6), developed by the Geophysical Fluid Dynamics Laboratory, is strongly eddying and includes a biogeochemical module with dissolved oxygen. The warming scenario shows that oxygen in the GoSL decreases and it is associated to changes in western boundary currents and wind patterns in the North Atlantic. We speculate that the large-scale changes behind the simulated decrease in GoSL oxygen have also been at play in the real world over the past century, although they are difficult to resolve in noisy atmospheric data.