Hi My Friends: A VUELO DE UN QUINDE EL BLOG., CryoSat was launched in 2010 to measure sea-ice thickness in the Arctic,
but data from the Earth-observing satellite have also been exploited
for other studies. High-resolution mapping of the topography of the
ocean floor is now being added to the ice mission’s repertoire.
An Earth-orbiting radar cannot see the ocean floor, but it can measure
ocean-surface height variations induced by the topography of the ocean
floor. The gravitational pull of the seafloor produces minor variations
in ocean surface height. Seafloor mapping by ships is much more accurate
than radar altimeter mapping, but to date only 10% of the seafloor has
been charted this way. A complete mapping of the deep oceans using ships
would take 200 ships navigating Earth, 24 hours a day, for an entire
year at a cost of billions of dollars. Mapping using satellite radars
can cover a larger area in a shorter amount of time. When interesting
features are discovered in satellite measurements, they can later be
surveyed in fine detail by ships.
Credits: Scripps Institution of Oceanography
Credits: Scripps Institution of Oceanography
Gravity field over the Pacific Ocean’s Emperor Seamounts based on
CryoSat, ERS and Geosat satellite altimeter measurements of
ocean-surface height. At this scale, the gravity field of the ocean
reflects seafloor topography, called bathymetry. The improved radar
measurements from CryoSat will be used to improve bathymetry. The
measurements will be used in the next generation of the seafloor maps in
Google Earth.
Credits: Scripps Institution of Oceanography/NOAA
Credits: Scripps Institution of Oceanography/NOAA
CryoSat was launched in 2010 to measure sea-ice thickness in the Arctic,
but data from the Earth-observing satellite have also been exploited
for other studies. High-resolution mapping of the topography of the
ocean floor is now being added to the ice mission’s repertoire.
The main objective of the polar-orbiting CryoSat is to measure the thickness of polar sea ice and monitor changes in the ice sheets that blanket Greenland and Antarctica.
The main objective of the polar-orbiting CryoSat is to measure the thickness of polar sea ice and monitor changes in the ice sheets that blanket Greenland and Antarctica.
But the satellite’s radar altimeter is not only able to detect tiny
variations in the height of the ice but it can also measure sea level.
The topography of the ocean surface mimics the rises and dips of the
ocean floor due to the gravitational pull. Areas of greater mass, such
as underwater mountains, have a stronger pull, attracting more water and
producing a minor increase in ocean-surface height.
Therefore, instruments that measure sea-surface height incidentally map the ocean floor in previously uncharted areas.
There have been several recent global gravity missions, such as ESA’s
GOCE satellite, that provide extraordinarily accurate measurements of
gravity at the spatial resolution of hundreds of kilometres.
But CryoSat’s radar altimeter can sense the gravity field at the ocean
surface, so that seafloor characteristics at scales of 5–10 km are
revealed. This is the first altimeter in 15 years to map the global
marine gravity field at such a high spatial resolution.
Recent studies at the Scripps Institution of Oceanography in San Diego,
USA, found that the range precision of CryoSat is at least 1.4 times
better than the US's Geosat or ESA's ERS-1.
They estimate that this improved range precision combined with three or
more years of ocean mapping will result in global seafloor topography –
bathymetry – that is 2–4 times more accurate than measurements currently
available
“We know more about the surfaces of Venus and Mars than we do about
the bathymetry of deep oceans,” said David Sandwell from the Scripps
Institution of Oceanography in the US.
“This new mapping from CryoSat will revolutionise our understanding of
ocean floor tectonics and reveal, perhaps, 10 000 previously uncharted
undersea volcanoes.”
Most satellite radar altimeters such as the one on the joint
CNES/NASA/Eumetsat/NOAA Jason-2 follow repeated ground-tracks every 10
days to monitor the changes in ocean topography associated with ocean
currents and tides.
CryoSat’s 369-day repeat cycle provides a dense mapping of the global
ocean surface at a track spacing of over 4 km. Three to four years of
data from CryoSat can be averaged to reduce the ‘noise’ due to currents
and tides and better chart the permanent topography related to marine
gravity.
ESAGuillermo Gonzalo Sánchez Achutegui
ayabaca@gmail.com
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ayabaca@yahoo.com
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