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Expanding Oxygen-Minimum Zones in the Tropical Oceans

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Science  02 May 2008:
Vol. 320, Issue 5876, pp. 655-658
DOI: 10.1126/science.1153847

Abstract

Oxygen-poor waters occupy large volumes of the intermediate-depth eastern tropical oceans. Oxygen-poor conditions have far-reaching impacts on ecosystems because important mobile macroorganisms avoid or cannot survive in hypoxic zones. Climate models predict declines in oceanic dissolved oxygen produced by global warming. We constructed 50-year time series of dissolved-oxygen concentration for select tropical oceanic regions by augmenting a historical database with recent measurements. These time series reveal vertical expansion of the intermediate-depth low-oxygen zones in the eastern tropical Atlantic and the equatorial Pacific during the past 50 years. The oxygen decrease in the 300- to 700-m layer is 0.09 to 0.34 micromoles per kilogram per year. Reduced oxygen levels may have dramatic consequences for ecosystems and coastal economies.

Oceanic dissolved-oxygen concentrations affect marine biogeochemical processes and have major impacts on the global carbon and nitrogen cycles (1). These concentrations are very sensitive to changes in air-sea fluxes and interior ocean advection, hence dissolved oxygen is an important parameter for understanding the ocean's role in climate (2). Important mobile macroorganisms are stressed or die under hypoxic conditions; that is, when oxygen concentrations drop below ∼60 to 120 μmol kg–1 (3). Hypoxia occurs at different oxygen concentrations among various species of macroorganisms, so the threshold is not precise. Regions with oxygen concentrations below about 10 μmol kg–1 are termed suboxic. In suboxic regions, nitrate (if present) becomes involved in respiration (1). Anoxic regions have no dissolved oxygen. At present, the intermediate-depth low-oxygen layers, here called the oxygen-minimum zone (OMZ), are suboxic in the eastern tropical Pacific Ocean and the northern reaches of the tropical Indian Ocean and are hypoxic in the tropical Atlantic Ocean (Fig. 1).

Fig. 1.

Climatological mean (18) dissolved oxygen concentrations (μmol kg–1 shown in color) at 400 m depth contoured at 20-μmol-kg–1 intervals from 10 to 230 μmol kg–1 (black lines) using Ocean Data View (19) software. Analyzed areas (A to F, Table 1, and Fig. 2) are enclosed by black boxes.

Oceanic dissolved oxygen concentrations have varied widely in the geologic past. For instance, paleoclimate records from the Cretaceous reveal profoundly altered biogeochemical cycles and dramatic consequences for ecosystems associated with reductions of ocean oxygen (4). The anoxic ocean at the end of the Permian (251 million years ago) is perhaps the most striking example, being associated with elevated atmospheric CO2 and massive terrestrial and oceanic extinctions (5, 6).

Climate models predict an overall decline in oceanic dissolved oxygen concentration and a consequent expansion of the OMZ under global warming conditions (7), with the largest declines occurring in extratropical regions. In the tropical regions, the models predict either zonal mean oxygen increases at depths of about 200 to 1000 m in the Atlantic and Pacific Oceans (7) or moderate zonal mean oxygen decreases (8). Predicted oxygen changes in the thermocline waters result largely from solubility changes in the upstream source waters, whereas changes in the deeper waters result mainly from decreased interior advection and ongoing oxygen consumption by remineralization of sinking particulate organic matter (7).

The global ocean has warmed substantially over the past 50 years (9), and strong interannual-to-decadal variations of oxygen have been observed in the upper 100 m (10). Long-term oxygen changes have been observed and reported in the subpolar and subtropical regions (11, 12). For instance, in the subarctic Pacific at Ocean Station Papa (50°N, 145°W), declining oxygen concentrations have been reported from depths of 100 to 400 m between 1956 and 2006 (11). Ocean oxygen data from the most oxygen-poor tropical regions of the OMZ are limited, but some regions exist for which historical data can be augmented with data from recent survey programs to construct relatively long, quasi-continuous oxygen time series.

We constructed and analyzed oxygen time series in some select areas of the tropical oceans (Fig. 1), using quality-controlled historical data from the HydroBase 2 database (13) and more recently measured oxygen profiles. Only oxygen data collected since 1960 were used because older oxygen data are rare and the net effect of changes in the observation system on our ability to document real ocean variability is not well understood. Unfortunately, even after 1960 oxygen data in most tropical regions are too sparse to construct useful time series, because in the past most oxygen profiles were collected almost exclusively from ships dedicated to oceanographic research. Recently, a small fraction of the 3000 Argo freely drifting floats that report vertical profiles of temperature and salinity over the upper 2000 m of the ocean via satellite at 10-day intervals (14) have been equipped with oxygen sensors. These floats provide valuable oxygen profiles (15) that were used to expand our time series through 2007 in the tropical Atlantic.

Reductions in observed minimum oxygen concentrations and vertical expansion of the OMZ since 1960 are apparent in three areas of the tropical Atlantic Ocean (Fig. 2). In the oxygen-poor region of the tropical North Atlantic (Fig. 1; 10° to 14°N, 20° to 30°W), a time series of historical data was augmented with data from meridional hydrographic sections nominally along 29°W in July 2003 and 23°W in July 2006 (Fig. 2A). No seasonal signal is present in this area (16). In the OMZ, core oxygen values decline and the OMZ expands vertically with time. The vertical extent of the layer with oxygen concentrations of <90 μmol kg–1 increased 85%, from a thickness of 370 m in 1960 to 690 m in 2006. In the near-equatorial Atlantic Ocean, oxygen values are higher to both the north and south (Fig. 1) because of the eastward transport of relatively oxygen-rich water within the complicated tropical current system (17). The relatively oxygen-rich water in the Atlantic Central Water originates from the poleward side of the subtropical gyre. Historical data, hydrocasts from three repeat sections along 23°W since 2000, and two recent profiles from an Argo float allowed construction of a time series (Fig. 2B) in the central equatorial Atlantic (Fig. 1; 3°S to 3°N, 18° to 28°W). This time series also shows some indication of a reduced concentration at the vertical oxygen minimum over time and a vertical expansion of the oxygen-poor OMZ. Similarly, a tropical South Atlantic (Fig. 1; 14° to 8°S, 4° to 12°E) time series (Fig. 2C) also shows a vertical expansion of the OMZ; although there are long gaps after the late 1980s, and no data between 2001 and 2007, a recent preliminary calibrated oxygen profile taken at 9°S, 8°E in March 2008 is consistent with the trend of an oxygen decline.

Fig. 2.

Dissolved oxygen concentration (μmol kg–1 shown in color) maps (20, 21) versus time (1960–2008) and pressure (1 dbar ∼ 1 m) with sample locations (white dots). (A) The eastern tropical North Atlantic (10° to 14°N, 20° to 30°W), contoured at 90 μmol kg–1 (thick white line). (B) The central equatorial Atlantic (3°S to 3°N, 28° to 18°W), contoured at 120 μmol kg–1 (thick white line). (C) The eastern tropical South Atlantic at (14° to 8°S, 4° to 12°E), contoured at 60 μmol kg–1 (thick white line). (D) The eastern equatorial Pacific Ocean (5°S to 5°N, 105° to 115°W), contoured at 60 μmol kg–1 (thick white line). (E) The central equatorial Pacific Ocean (5°S to 5°N 165° to 175°W), contoured at 90 and 120 μmol kg–1 (thick white lines). (F) The eastern equatorial Indian Ocean (5°S to 0, 90° to 98°E), contoured at 60 μmol kg–1 (thick white line).

The OMZ in the tropical North and South Pacific Oceans reaches suboxic (and, in the most oxygen-poor regions, nearly anoxic) levels (Fig. 1), so detecting changes in minimum values there is difficult. Furthermore, data in the most oxygen-poor regions are too sparse to allow the construction of quasi-continuous time series. However, as in the Atlantic Ocean, Pacific equatorial currents carry relatively oxygen-rich water eastward toward the most oxygen-poor regions of the OMZ in both hemispheres. Historical hydrographic data in the eastern equatorial Pacific Ocean (Fig. 1; 5°S to 5°N, 105° to 115°W), augmented with data collected during some recent Tropical Atmosphere Ocean project mooring maintenance cruises along 110°W, constitute a time series (Fig. 2D) that reveals a vertical expansion of the OMZ. However, a depth-integrated oxygen trend there is not statistically significantly different from zero when a stringent 95% confidence criterion is used (Table 1). Slightly higher values from 1980 to 1990 may be caused by sample locations biased toward the equator, where more oxygen-rich waters are advected eastward from the west. In the central equatorial Pacific (Fig. 1; 5°S to 5°N, 165° to 175°W), oxygen concentrations within the OMZ are more variable (Fig. 2E). Nevertheless, the OMZ thickness expands over the duration of the time series. This vertical expansion with time is not closely related to a temperature increase; in both areas of the equatorial Pacific, the temperature in the 300- to 700-m layer slightly decreases, as does the oxygen content (Table 1).

Table 1.

Linear trends of temperature and oxygen with 95% confidence intervals (22) since 1960 in a 300- to 700-m layer for select ocean areas, and integrated oxygen loss, assuming a nominal density of 1027.2 kg m–3.

View this table:

In the Indian Ocean, the lowest oxygen values in the OMZ are not located in the eastern tropics as they are in the Atlantic and Pacific Oceans, but to the north in the Arabian Sea and the Bay of Bengal (Fig. 1). In addition, minimum oxygen concentrations within the Indian Ocean OMZ are generally deeper (near 800 m) than in the other two oceans. In the northern Indian Ocean OMZ, sources and sinks of oxygen are nearly in apparent balance; circulation there appears relatively stagnant, with detritus falling from the highly productive waters above and rapidly depleting oxygen below. As in the eastern tropical Pacific Ocean, oxygen values in the northern Indian Ocean OMZ are suboxic, and the sparse data distributions in the most oxygen-poor regions preclude the construction of long quasi-continuous time series there. However, the recent occupation of a meridional section nominally along 95°E made possible the construction of an eastern equatorial Indian Ocean time series (Fig. 1; 5°S to 0°, 90° to 98°E), despite gaps in data since the mid-1980s (Fig. 2F). Unlike the other time series presented here, there is neither an obvious increase of the vertical extent of the OMZ nor a visible decrease in oxygen minimum values. Statistics of the layer at a depth of 300 to 700 m reveal a weak oxygen decrease not different from zero at 95% confidence (Table 1). Time series from the early 1960s to the late 1990s (not shown) in the western equatorial Indian Ocean, the Arabian Sea, and the Bay of Bengal show similar constancy in the tropical Indian Ocean OMZ. Collectively, these results suggest that over the past few decades there has been no substantial change in the tropical Indian Ocean OMZ.

As an auxiliary benefit, the constancy of OMZ characteristics in the Indian Ocean time series suggests that the changes observed in the tropical Atlantic and Pacific Ocean OMZ characteristics are not based on changes in observation techniques. This concern was also tested in the oxygen-rich deep-water formation region of the Labrador Sea, for which a very well-sampled time series can be constructed from 1960 to the present. There, no trend toward lower oxygen values is apparent, supporting the claim that oceanic oxygen measurements taken over the past 50 years are not subject to large observational biases that may produce spurious temporal trends.

The tropical ocean OMZs in the central and eastern tropical Atlantic and equatorial Pacific Oceans appear to have expanded and intensified during the past 50 years. Despite the sparseness of observations, the time series used show that the decline in oxygen content has been most intense in the tropical Atlantic, where at present hypoxic regions are small as compared with the Pacific and Indian Oceans. For these reasons, the Atlantic may also have the most potential for large increases in the area of hypoxic regions.

The observational analysis presented here supports climate model predictions of dissolved oxygen declines in the tropical ocean (7, 8) and an expansion of the tropical OMZs due to a contribution of thermal, dynamical, and biogeochemical factors (8). The observed oxygen declines reported here of 0.09 to 0.34 μmol kg–1year–1 for 300- to 700-m depths (Table 1) are somewhat smaller than those reported in the North Pacific (11) at 100 to 400 m. Together, these trends affect carbon and nitrogen cycles, with fundamental implications for marine ecosystems and thereby fisheries resource management issues. Given climate model projections, and the geological record that indicates times of widely distributed suboxic regions, sustained global ocean measurements of dissolved oxygen concentrations are needed (for instance, by equipping more Argo floats with well-calibrated dissolved oxygen sensors) to more closely monitor variations in the strength and extent of the OMZ.

References and Notes

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