Abstract
Abstract. In the global ocean, the number of reported hypoxic sites (oxygen <30% saturation) is on the rise both near the coast and in the open ocean. But unfortunately, most of the papers on hypoxia only present oxygen data from one or two years, so that we often lack a long-term perspective on whether oxygen levels at these locations are decreasing, steady or increasing. Consequently, we cannot rule out the possibility that many of the newly reported hypoxic areas were hypoxic in the past, and that the increasing number of hypoxic areas partly reflects increased research and monitoring efforts. Here we address this shortcoming by computing oxygen concentration trends in the global ocean from published time series and from time series that we calculated using a global oxygen database. Our calculations reveal that median oxygen decline rates are more severe in a 30 km band near the coast than in the open ocean (>100 km from the coast). Percentages of oxygen time series with negative oxygen trends are also greater in the coastal ocean than in the open ocean. Finally, a significant difference between median published oxygen trends and median trends calculated from raw oxygen data suggests the existence of a publication bias in favor of negative trends in the open ocean.
Highlights
Several studies suggest that oxygen levels are generally decreasing both in the coastal ocean (Dıaz and Rosenberg, 2008) and in the deep ocean (Keeling and Garcia, 2002)
Comparing the summary results from published time series over the 1976–2000 period (Table 4) with the summary results obtained with time series calculated from raw data over the same time period (Table 8), we find no significant difference between published and calculated median trends for the coastal band (0–30 km) and for the 30–100 km band
– The percentage of negative oxygen trends is significantly greater in the coastal ocean (64.2%) than in the open ocean (49.1%)
Summary
Several studies suggest that oxygen levels are generally decreasing both in the coastal ocean (Dıaz and Rosenberg, 2008) and in the deep ocean (Keeling and Garcia, 2002). This is cause for concern as lower concentrations of dissolved oxygen (DO) have adverse effects on marine life, ranging from reduced growth and reproductive capacity to habitat avoidance and death. At other sites on the continental shelf and in the deep ocean, changes in ocean circulation (Gilbert et al, 2005; Monteiro et al, 2006) or in winter ventilation (Whitney et al, 2007) play a role in lowering oxygen concentrations. There are early indications that this may already be detectable (Stramma et al, 2008; Johnson and Gruber, 2007; Stramma et al, 2010), but interdecadal changes in ocean circulation could have played a role in these trends (Frolisher et al, 2009)
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