Hi My Friends: A VUELO DE UN QUINDE EL BLOG., ESA astronaut André Kuipers is running experiments on the International
Space Station that are shedding light on conditions deep inside Earth.
Orbiting some 400 km above us, Geoflow is offering insights into the
inner workings of our planet.
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Geoflow data from the International Space Station showing how a liquid
between two revolving concentric spheres moves as the temperature
between the outer and inner sphere changes.
Six European teams led by the University of Cottbus in Germany
recreated aspects of mantle flow in the Geoflow laboratory. Experiments
simulating these conditions can verify and improve computer models.
Understanding how Earth’s mantle flows is a major interest for
geophysics because it could help to explain earthquakes or volcanic
eruptions. The results could also benefit industry by improving
spherical gyroscopes, bearings and centrifugal pumps, for example.
Credits: ESA
ESA astronaut André Kuipers is running experiments on the International
Space Station that are shedding light on conditions deep inside Earth.
Orbiting some 400 km above us, Geoflow is offering insights into the
inner workings of our planet.
Descending 3000 km under our feet, Earth’s mantle is a semi-solid fluid under our thin outer crust. The highly viscous layers vary with temperature, pressure and depth.
Descending 3000 km under our feet, Earth’s mantle is a semi-solid fluid under our thin outer crust. The highly viscous layers vary with temperature, pressure and depth.
Understanding how the mantle flows is a major interest for geophysics
because it could help to explain earthquakes or volcanic eruptions.
Computers can model it, but how can scientists be sure they are correct?
The deepest that humans have ever drilled is just over 12 km, so investigating the mantle directly is out of reach for th
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The complete Geoflow laboratory experiment that was installed on the
International Space Station. Geoflow is used to verify and improve
computer models of fluid convection.
Six European teams led by the University of Cottbus in Germany recreated aspects of mantle flow in the Geoflow laboratory.
Understanding how Earth’s mantle flows is a major interest for
geophysics because it could help to explain earthquakes or volcanic
eruptions. The results could also benefit industry by improving
spherical gyroscopes, bearings and centrifugal pumps, for example.
Credits: ESA
Instead of probing Earth’s depths directly, six European teams led by
the University of Cottbus in Germany looked to recreate aspects of
mantle flow in a laboratory. Experiments simulating these conditions can
verify and improve the computer models.
This poses a different problem, however. How can gravity be simulated without Earth’s gravity itself influencing the results?
The solution is to send an experiment to our largest weightless laboratory: the International Space Station.
Inside the Geoflow experiment two revolving
concentric spheres heat a liquid. By observing how the liquid moves in
response to temperature differences, scientists are verifying and
improving computer models of fluid convection.
The results could benefit industry by improving spherical gyroscopes, bearings and centrifugal pumps, for example.
Credits: ESA
Planet in a box
ESA sponsored the development of an experiment that mimics the geometry of a planet. Called Geoflow, it contains two revolving concentric spheres with a liquid between them.
ESA sponsored the development of an experiment that mimics the geometry of a planet. Called Geoflow, it contains two revolving concentric spheres with a liquid between them.
The inner sphere represents Earth’s core, with the outer sphere acting as the crust. The liquid, of course, is the mantle.
Free from the influence of Earth’s gravity, a high-voltage electrical field creates artificial gravity for the experiment.
Free from the influence of Earth’s gravity, a high-voltage electrical field creates artificial gravity for the experiment.
As the spheres rotate slowly and a temperature difference is created
between the shells, movement in the liquid is closely monitored. The
temperatures can be controlled down to a tenth of a degree.
This Envisat radar image features six of Hawaii’s eight major volcanic
islands. Visible from right to left are the Big Island of Hawaii,
Kahoolawe, Maui, Lanai, Molokai and Oahu. In addition to two other major
islands, there are also 124 islets.
This image was created by combining three Envisat radar scans (27 March
2006, 16 April 2007 and 21 January 2008) of the same area. The colours
in the image result from variations in the surface that occurred between
acquisitions.
Credits: ESA
André has seen plumes of hotter liquid rising towards the outer shell – as predicted by computer simulations.
Mushroom-like plumes in fluids exposed to strong temperature differences
might explain the Hawaiian line of volcanoes in the South Pacific.
A better understanding of our planet is not the only outcome of Geoflow.
The results could also benefit industry by improving spherical
gyroscopes, bearings and centrifugal pumps, for example.
ESAGuillermo Gonzalo Sánchez Achutegui
ayabaca@gmail.com
ayabaca@hotmail.com
ayabaca@yahoo.com
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