Changes in iron supply to oceanic plankton are thought to have a significant effect on concentrations of atmospheric carbon dioxide by altering rates of carbon sequestration, a theory known as the 'iron hypothesis'. For this reason, it is important to understand the response of pelagic biota to increased iron supply. Here we report the results of a mesoscale iron fertilization experiment in the polar Southern Ocean, where the potential to sequester iron-elevated algal carbon is probably greatest. Increased iron supply led to elevated phytoplankton biomass and rates of photosynthesis in surface waters, causing a large drawdown of carbon dioxide and macronutrients, and elevated dimethyl sulphide levels after 13 days. This drawdown was mostly due to the proliferation of diatom stocks. But downward export of biogenic carbon was not increased. Moreover, satellite observations of this massive bloom 30 days later, suggest that a sufficient proportion of the added iron was retained in surface waters. Our findings demonstrate that iron supply controls phytoplankton growth and community composition during summer in these polar Southern Ocean waters, but the fate of algal carbon remains unknown and depends on the interplay between the processes controlling export, remineralisation and timescales of water mass subduction.
Increasing heat content of the global ocean dominates the energy imbalance in the climate system 1 . Here we show that ocean heat gain over the 0-2,000 m layer continued at a rate of 0.4-0.6 W m −2 during 2006-2013. The depth dependence and spatial structure of temperature changes are described on the basis of the Argo Program's 2 accurate and spatially homogeneous data set, through comparison of three Argo-only analyses. Heat gain was divided equally between upper ocean, 0-500 m and 500-2,000 m components. Surface temperature and upper 100 m heat content tracked interannual El Niño/Southern Oscillation fluctuations 3 , but were o set by opposing variability from 100-500 m. The net 0-500 m global average temperature warmed by 0.005 • C yr −1 . Between 500 and 2,000 m steadier warming averaged 0.002 • C yr −1 with a broad intermediate-depth maximum between 700 and 1,400 m. Most of the heat gain (67 to 98%) occurred in the Southern Hemisphere extratropical ocean. Although this hemispheric asymmetry is consistent with inhomogeneity of radiative forcing 4 and the greater area of the Southern Hemisphere ocean, ocean dynamics also influence regional patterns of heat gain.Global ocean sampling of water-column temperature in the twentieth century was spatially and temporally sparse 5 , characterized by strong coverage biases towards the Northern Hemisphere, towards the continental coastlines, and seasonally towards summer. Roughly half a million temperature/salinity profiles to at least 1,000 m were collected by research vessels, mostly in the past 50 years. Additional lower accuracy and shallower temperature-only data have been obtained from commercial and naval vessels. These help to mitigate the coverage deficiencies but raise additional concerns regarding measurement bias errors 6 .Today the Argo Program 2 provides systematic coverage of global ocean temperature/salinity from 0-2,000 m using 3,500 autonomous profiling floats spaced about every 3 • of latitude and longitude, each providing a temperature/salinity profile every 10 days. Profiling float technology 7 allows data to be collected without a ship by long-lived free-drifting instruments. Argo has collected 1.2 million temperature/salinity profiles and continues to provide 10,000 profiles per month, with far greater spatial and temporal homogeneity than that achieved historically. Previous investigations of ocean heat content 5 have combined Argo and historical data of variable quality, and these studies have been impacted by coverage and measurement bias issues. Here we estimate ocean heat gain over the 2006-2013 period for which Argo coverage is global (Methods), and through the exclusive use of Argo data with uniformly high quality.Argo's ocean temperature data set is invaluable for estimating the net radiation balance of the Earth. The deduced excess of downward over outgoing radiation 8 driving global warming is too small to measure directly as radiative fluxes 9 . About 93% of this net planetary energy increase is stored in the oceans 1 , a result of the ...
More than 90% of the heat energy accumulation in the climate system between 1971 and the present has been in the ocean. Thus, the ocean plays a crucial role in determining the climate of the planet. Observing the oceans is problematic even under the most favourable of conditions. Historically, shipboard ocean sampling has left vast expanses, particularly in the Southern Ocean, unobserved for long periods of time. Within the past 15 years, with the advent of the global Argo array of pro ling oats, it has become possible to sample the upper 2,000 m of the ocean globally and uniformly in space and time. The primary goal of Argo is to create a systematic global network of pro ling oats that can be integrated with other elements of the Global Ocean Observing System. The network provides freely available temperature and salinity data from the upper 2,000 m of the ocean with global coverage. The data are available within 24 hours of collection for use in a broad range of applications that focus on examining climate-relevant variability on seasonal to decadal timescales, multidecadal climate change, improved initialization of coupled ocean-atmosphere climate models and constraining ocean analysis and forecasting systems.
An increase in the circulation of the South Pacific Ocean subtropical gyre, extending from the sea surface to middepth, is observed over 12 years. Datasets used to quantify the decadal gyre spinup include satellite altimetric height, the World Ocean Circulation Experiment (WOCE) hydrographic and float survey of the South Pacific, a repeated hydrographic transect along 170°W, and profiling float data from the global Argo array. The signal in sea surface height is a 12-cm increase between 1993 and 2004, on large spatial scale centered at about 40°S, 170°W. The subsurface datasets show that this signal is predominantly due to density variations in the water column, that is, to deepening of isopycnal surfaces, extending to depths of at least 1800 m. The maximum increase in dynamic height is collocated with the deep center of the subtropical gyre, and the signal represents an increase in the total counterclockwise geostrophic circulation of the gyre, by at least 20% at 1000 m. A comparison of WOCE and Argo float trajectories at 1000 m confirms the gyre spinup during the 1990s. The signals in sea surface height, dynamic height, and velocity all peaked around 2003 and subsequently began to decline. The 1990s increase in wind-driven circulation resulted from decadal intensification of wind stress curl east of New Zealand—variability associated with an increase in the atmosphere’s Southern Hemisphere annular mode. It is suggested (based on altimetric height) that midlatitude gyres in all of the oceans have been affected by variability in the atmospheric annular modes on decadal time scales.
The Argo profiling float project will enable, for the first time, continuous global observations of the temperature, salinity, and velocity of the upper ocean in near‐real time.This new capability will improve our understanding of the ocean's role in climate, as well as spawn an enormous range of valuable ocean applications. Because over 90% of the observed increase in heat content of the air/land/sea climate system over the past 50 years occurred in the ocean [Leuitus et al., 2001], Argo will effectively monitor the pulse of the global heat balance.The end of 2003 was marked by two significant events for Argo. In mid‐November 2003, over 200 scientists from 22 countries met at Argo's first science workshop to discuss early results from the floats. Two weeks later, Argo had 1000 profiling floats—one‐third of the target total—delivering data. As of 7 May that total was 1171.
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