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Argo is a system for observing temperature, salinity, and currents in the Earth's oceans. The real-time data it provides is used in climate and oceanographic research.^[1]^[2]

Argo consists of a fleet of approximately 3000 small (20-30 kg) drifting robotic probes (profiling floats) deployed worldwide. Profiling floats are commonly used in oceanography and become "Argo floats" only when they are deployed in conformity with the Argo data policy. In most cases probes drift at a depth of 1000 metres (the so-called parking depth) and, every 10 days, by changing their buoyancy, dive to a depth of 2000 metres and then move to the sea-surface, measuring conductivity and temperature profiles as well as pressure. From these, salinity and density can be calculated. Seawater density is important in determining large-scale motions in the ocean. Average current velocities at 1000 metres' depth are directly measured by the distance and direction a float drifts while parked at that depth, which is determined by GPS or Argos system positions at the surface. The data are transmitted to shore via satellite, and are freely available to everyone, without restrictions. The Argo program is named after the Greek mythical ship Argo and was chosen to emphasize the complementary relationship of Argo with the Jason satellite altimeters.

File:Argo 2013-07-countries.jpg

Map of the Argo float network as of July 2013

International collaboration

The Argo program is a collaborative partnership of more than 30 nations from all continents (most shown on the graphic above) to provide a seamless global array allowing any country to explore the ocean environment. Argo is a key component of the Global Ocean Observing System (GOOS). Argo is coordinated by the Argo Steering Team – an international body of scientists and technical experts that meets once per year. The Argo data stream is managed the Argo Data Management Team . Overall coordination is assisted through the Argo Information Centre, an office belonging to the Intergovernmental Oceanographic Commission , (which also coordinates GOOS) and the World Meteorological Organization . Argo is also supported by GEO – the Group on Earth Observations, and has been endorsed since its early beginnings by the World Climate Research Programme’s CLIVAR Project (Variability and predictability of the ocean-atmosphere system), and by the Global Ocean Data Assimilation Experiment (GODAE OceanView).

History

A program called Argo was first proposed at OceanObs 1999 which was a conference organised by international agencies with the aim of creating a coordinated approach to ocean observations. The original Argo prospectus was created by a small group of scientists who described a program that would have a global array of about 3000 floats in place by sometime in 2007. The 3000-float array was achieved in November 2007 and was global. The Argo Steering Team met for the first time in 1999 in Maryland (USA) and outlined the principles of global data sharing. The Argo Steering Team made a 10-year report to OceanObs-2009 ^[3] and received suggestions on how the array might be improved. These suggestions included enhancing the array at high latitudes, in marginal seas (such as the Gulf of Mexico and the Mediterranean) and along the equator, improved observation of strong boundary currents (such as the Gulf Stream and Kuroshio), extension of observations into deep water and the addition of sensors for monitoring biological and chemical changes in the oceans. In November 2012 an Indian float in the Argo array gathered the one-millionth profile (twice the number collected by research vessels during all of the 20th century) an event that was reported in several press releases.^[4] ^[5]

Float design and operation

The critical capability of an Argo float is its ability to rise and descend in the ocean on a programmed schedule. The floats do this by changing their effective density. The density of any object is given by its mass divided by its volume. The Argo float keeps its mass constant, but by altering its volume, it changes its density. To do this, a hydraulic piston is used to push mineral oil out of the float and expand a rubber bladder at the bottom end of the float. As the bladder expands, the float becomes less dense than seawater and rises to the surface. Upon finishing its tasks at the surface, the float withdraws the piston and descends again.^[6]

A typical Argo float is a cylinder just over 1 metre long and 14 cm across with a hemispherical cap. Thus it has a minimum volume of about 16,600 cubic centimetres. At Ocean Station Papa in the Gulf of Alaska the temperature and salinity at the surface might be about 6°C and 32.55 parts per thousand giving a density of sea-water of 1.0256 g/cubic cm. At a depth of 2000 metres (pressure of 2000 decibars) the temperature might be 2°C and the salinity 34.58 parts per thousand. Thus, including the effect of pressure (water is slightly compressible) the density of sea-water is about 1.0369 g/cubic cm. The change in density divided by the deep density is 0.0109.

The float has to match these densities if it is to reach 2000 metres depth and then rise to the surface. Since the density of the float is its mass divided by volume, it needs to change its volume by 0.0109 x 16,600 = 181 cubic centimetres to drive that excursion. All Argo floats carry sensors to measure the temperature and salinity of the ocean as they vary with depth, but an increasing number of floats also carry other sensors, such as for measuring dissolved oxygen and ultimately other variables of biological and chemical interest such as chlorophyll, nutrients and pH. An extension to the Argo project called BioArgo is being developed and, when implemented, will add a biological and chemical component to this method of sampling the oceans.

The antenna for satellite communications is mounted at the top of the float which extends clear of the sea surface after it completes its ascent. The ocean is saline, hence an electrical conductor, so that radio communications from under the sea surface are not possible. Early in the program Argo floats exclusively used slow mono-directional satellite communications but the majority of floats being deployed in mid-2013 use rapid bi-directional communications. The result of this is that Argo floats now transmit much more data than was previously possible and they spend only about 20 minutes on the sea surface rather than 8–12 hours, greatly reducing problems such as grounding and bio-fouling.

The average life span of Argo floats has increased greatly since the program began, first exceeding 4-year mean lifetime for floats deployed in 2005. Ongoing improvements should result in further extensions to 6 years and longer.

Array Design

The original plan advertised in the Argo prospectus called for a nearest-neighbour distance between floats, on average, of 3° latitude by 3° longitude. This allowed for higher resolution (in kilometres) at high latitudes, both north and south, and was considered necessary because of the decrease in the Rossby radius of deformation which governs the scale of oceanographic features, such as eddies. By 2007 this was largely achieved, but the target resolution has never yet been completely achieved in the deep southern ocean.^[7]

Efforts are being made to complete the original plan in all parts of the world oceans but this is difficult in the deep Southern Ocean as deployment opportunities occur only very rarely.

As mentioned in the history section enhancements are now planned in the equatorial regions of the oceans, in boundary currents and in marginal seas. This requires that the total number of floats be increased from the original plan of 3000 floats to a 4000-float array.

One consequence of the use of profiling floats to sample the ocean is that seasonal bias can be removed. The diagram opposite shows the count of all float profiles acquired each month by Argo south of 30°S (upper curve) from the start of the program to November 2012 compared with the same diagram for all other data available. The lower curve shows a strong annual bias with 4 times as many profiles being collected in austral summer than in austral winter. For Argo the ratio is less than 1.2.

Data Access

One of the critical features of the Argo model is that of global and unrestricted access to data in near real-time. When a float transmits a profile it is quickly converted to a format that can be inserted on the GTS (Global Telecommunications System). The GTS is operated by the World Meteorological Organisation, or WMO, specifically for the purpose of sharing data needed for weather forecasting. Thus all nations who are members of the WMO receive all Argo profiles within a few hours of the acquisition of the profile. Data are also made available through ftp and WWW access via two Argo Global Data Centres (or GDACs) a French GDAC and a US GDAC.

About 90% of all profiles acquired are made available to global access within 24 hours, with the remaining profiles becoming available soon thereafter.

For a researcher to use data acquired via the GTS or from the Argo Global Data Centres (GDACs) does require programming skills. The GDACs supply multi-profile files that are a native file format for Ocean DataView. For any day there are files with names like 20121106_prof.nc that are called multi-profile files. This example is a file specific to 6 November 2012 and contains all profiles in a single NetCDF file for one ocean basin. The GDACs identify three ocean basins, Atlantic, Indian and Pacific. Thus three multi-profile files will carry every Argo profile acquired on that specific day.

A user who wants to explore Argo data but lacks programming skills might like to download the Argo Global Marine Atlas ^[8] which is an easy-to-use utility that allows the creation of products based on Argo data such as the salinity section shown above, but also horizontal maps of ocean properties, time series at any location etc. This Atlas also carries an “update” button that allows data to be updated periodically. The Argo Global Marine Atlas is maintained at the Scripps Institution of Oceanography in La Jolla, California.

For users interested in gridded fields based on Argo data, visit the webpage maintained by Argo with a list of freely available grids.

Argo data can also be displayed in Google Earth with a layer developed by the Argo Technical Coordinator. Instructions on how to use this layer can be found at here.

Irrespective of the methods used to acquire and explore Argo data it is essential that users familiarize themselves with the structure of Argo files, the nature of Argo floats and the meaning of the quality control flags. A useful document is the Argo User manual. It is strongly recommended that users read this manual before beginning to explore Argo data. There is also a webpage maintained by the Argo Steering Team with some tips on how to begin using Argo data.

Data Results

Number of papers, by year, published in refereed journals and that are extensively or totally dependent on the availability of Argo data.

Argo is now the dominant source of information about the climatic state of the oceans and is being widely used in many publications on as seen in the diagram opposite. Topics addressed include air-sea interaction, ocean currents, interannual variability, El Niño, mesoscale eddies, water mass properties and transformation, essentially Argo is being used in all topics in physical oceanography. Argo is also now permitting direct computations of the global ocean heat content.

A notable recent paper was published by Durack and Wijffels and analyses global changes in surface salinity patterns.^[9]

They determine that areas of the world with high surface salinity are getting saltier and areas of the world with relatively low surface salinity are getting fresher. This has been described as 'the rich get richer and the poor get poorer'. Scientifically speaking, the distributions of salt are governed by the difference between precipitation and evaporation. Areas, such as the northern North Pacific Ocean, where precipitation dominates evaporation are fresher than average. The implication of their result is that the Earth is seeing an intensification of the global hydrological cycle. Argo data are also being used to drive computer models of the climate system leading to improvements in the ability of nations to forecast seasonal climate variations.^[10]

References

^ Argo Begins Systematic Global Probing of the Upper Oceans Toni Feder, Phys. Today 53, 50 (2000), doi:10.1063/1.1292477
^ Richard Stenger (September 19, 2000). "Flotilla of sensors to monitor world's oceans". CNN. Archived from the original on 6 November 2007. Retrieved 2007-10-28. {{cite news}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)
^ https://abstracts.congrex.com/scripts/jmevent/abstracts/FCXNL-09A02a-1727773-1-Argo_CWP_Reformatv2.pdf Argo – A decade of progress (community white paper submitted to OceanObs’09
^ http://www.bodc.ac.uk/about/news_and_events/argo_millionth_profile.html British Oceanographic Data Centre celebrates one million profiles.
^ http://www.unesco.org/new/en/media-services/single-view/news/argo_collects_its_one_millionth_observation/#.UiS-m9JwpyI UNESCO celebrates on million Argo profiles.
^ http://www.argo.ucsd.edu/How_Argo_floats.html UCSD description on 'how Argo floats work'
^ https://abstracts.congrex.com/scripts/jmevent/abstracts/FCXNL-09A02a-1727773-1-Argo_CWP_Reformatv2.pdf Argo – A decade of progress (community white paper submitted to OceanObs’09
^ http://www-argo.ucsd.edu/Marine_Atlas.html Argo Global Marine Atlas by Megan Scanderbeg
^ Durack, P. J., S. E. Wijffels, and R. J. Matear, 2012: Ocean Salinities Reveal Strong Global Water Cycle Intensification During 1950 to 2000. Science, 336, 455-458,http://www.sciencemag.org/content/336/6080/455.abstract
^ GODAE/OceanView https://www.godae-oceanview.org

External links

The Argo Portal
International Argo Information Centre
Argo at the Scripps Institution of Oceanography, San Diego
Realtime Interactive Map
Realtime Google Earth File
Coriolis Global Argo Data Server - EU Mirror
FNMOC Global Argo Data server - US Mirror
NOAA/Pacific Marine Environmental Laboratory profiling float project deploys floats as part of the Argo program, provides data on-line, and is active in delayed-mode salinity calibration and quality control for US Argo floats.
Changing conditions in the Gulf of Alaska as seen by Argo
Government of Canada, Department of Fisheries and Oceans, Argo Project
A New World View Argo explorations article by Scripps Institution of Oceanography
The Argo Blog
JCOMMOPS
Argo on NOSA

[1] Argo Begins Systematic Global Probing of the Upper Oceans Toni Feder, Phys. Today 53, 50 (2000), doi:10.1063/1.1292477

[2] Richard Stenger (September 19, 2000). "Flotilla of sensors to monitor world's oceans". CNN. Archived from the original on 6 November 2007. Retrieved 2007-10-28. {{cite news}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)

[3] ttps://abstracts.congrex.com/scripts/jmevent/abstracts/FCXNL-09A02a-1727773-1-Argo_CWP_Reformatv2.pdf Argo – A decade of progress (community white paper submitted to OceanObs’09

[4] ttp://www.bodc.ac.uk/about/news_and_events/argo_millionth_profile.html British Oceanographic Data Centre celebrates one million profiles.

[5] ttp://www.unesco.org/new/en/media-services/single-view/news/argo_collects_its_one_millionth_observation/#.UiS-m9JwpyI UNESCO celebrates on million Argo profiles.

[6] ttp://www.argo.ucsd.edu/How_Argo_floats.html UCSD description on 'how Argo floats work'

[7] ttps://abstracts.congrex.com/scripts/jmevent/abstracts/FCXNL-09A02a-1727773-1-Argo_CWP_Reformatv2.pdf Argo – A decade of progress (community white paper submitted to OceanObs’09

[8] ttp://www-argo.ucsd.edu/Marine_Atlas.html Argo Global Marine Atlas by Megan Scanderbeg

[9] Durack, P. J., S. E. Wijffels, and R. J. Matear, 2012: Ocean Salinities Reveal Strong Global Water Cycle Intensification During 1950 to 2000. Science, 336, 455-458,http://www.sciencemag.org/content/336/6080/455.abstract

[10] GODAE/OceanView https://www.godae-oceanview.org

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@@ Line 9: / Line 9: @@
 | archiveurl= http://web.archive.org/web/20071106111634/http://archives.cnn.com/2000/NATURE/09/19/ocean.sensors/index.html| archivedate= 6 November 2007 <!--DASHBot-->| deadurl= no}}</ref>
-Argo consists of a fleet of approximately 3000 small (20-30 kg) drifting robotic probes ("Argo floats") deployed worldwide. In most cases probes drift at a depth of 1000 metres (the so-called parking depth) and, every 10 days, by changing their [[buoyancy]], dive to a depth of 2000 metres and then move to the sea-surface, measuring conductivity and temperature profiles as well as [[pressure]]. From these, salinity and [[density]] can be calculated.  Seawater density is important in determining large-scale motions in the ocean.  Average current velocities at 1000 metres' depth are directly measured by the distance and direction a float drifts while parked at that depth, which is determined by [[GPS]] or [[Argos system]] positions at the surface. The data are transmitted to shore via satellite, and are freely available to everyone, without restrictions.  The Argo program is named after the Greek mythical ship [[Argo]] and was chosen to emphasize the complementary relationship of Argo with the [[Jason]] satellite altimeters.
+Argo consists of a fleet of approximately 3000 small (20-30 kg) drifting robotic probes (profiling floats) deployed worldwide.  Profiling floats are commonly used in oceanography and become "Argo floats" only when they are deployed in conformity with the Argo data policy. In most cases probes drift at a depth of 1000 metres (the so-called parking depth) and, every 10 days, by changing their [[buoyancy]], dive to a depth of 2000 metres and then move to the sea-surface, measuring conductivity and temperature profiles as well as [[pressure]]. From these, salinity and [[density]] can be calculated.  Seawater density is important in determining large-scale motions in the ocean.  Average current velocities at 1000 metres' depth are directly measured by the distance and direction a float drifts while parked at that depth, which is determined by [[GPS]] or [[Argos system]] positions at the surface. The data are transmitted to shore via satellite, and are freely available to everyone, without restrictions.  The Argo program is named after the Greek mythical ship [[Argo]] and was chosen to emphasize the complementary relationship of Argo with the [[Jason]] satellite altimeters.
 [[Image:Argo 2013-07-countries.jpg|thumb|450px|right|Map of the Argo float network as of July 2013]]

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