A time-series mosaic of surface wind speed measurements
under Hurricanes Kilo, Ignacio and Jimena is shown in this animation.
Data from three satellite microwave radiometer missions: ESA’s L-band SMOS, NASA’s L-band SMAP and Japan’s C-band AMSR-2 are combined to reveal the track of each hurricane and maximum wind speed measured by each sensor at the ocean surface.
From ESA
ESA’s SMOS and two other satellites are together providing insight into how surface winds evolve under tropical storm clouds in the Pacific Ocean.
This new information could to help predict extreme weather at sea.
This year, a particularly strong El NiƱo is resulting in much higher surface ocean temperatures than normal.
The surplus heat that is being drawn into the atmosphere is helping to breed tropical cyclones – Pacific Ocean monsters.
With eight major hurricanes already, this year’s hurricane season is the fifth most active in the Eastern Tropical Pacific since 1971.
At the end of August, three category-4 hurricanes developed in parallel near Hawaii.
True-colour composite from the MODIS instrument on NASA’s Terra satellite
of hurricanes Kilo (left), Ignacio (centre) and Jimena (right) on 29
August 2015.
All three were category-4 hurricanes and spanned the
central and eastern Pacific basins.
The bright bands in the images are
sunglint where solar radiation from the Sun has reflected from Earth
back to the satellite sensor.
The Copernicus Sentinel-3A satellite,
expected to be launched in late 2015, will provide images such as these
at 300 m resolution and in 21 bands from its Ocean and Land Colour
Imager along with thermal infrared images from its Sea and Land
Temperature Radiometer.
A collage from NASA’s Terra satellite captured the Kilo, Ignacio and Jimena hurricanes beautifully.
However, a special set of eyes is needed to see through the clouds that are so characteristic of these mighty storms so that the speed of the wind at the ocean surface can be measured.
This information is essential to forecast marine weather and waves, and to predict the path that the storm may take so that mariners receive adequate warning of danger.
The microwave detector on SMOS yields information on soil moisture and ocean salinity.
Going beyond its original scientific objectives, ESA pioneered the application of SMOS measurements to study wind speeds over the ocean.
Hurricanes change temperature of sea surface
Sea-surface temperature anomalies reveal cold-water wakes trailing
behind the Kilo, Ignacio and Jimena hurricanes, highlighting the power
these winds have in stirring the upper ocean and bringing cooler deep
waters to the ocean surface.
Air–sea interaction on this scale has
implications for modelling teams at hurricane forecasting centres and
for ocean forecasting systems such as the Copernicus Marine
Environmental Monitoring Service.
Ifremer–N. Reul/ESA SMOS+STORM project and REMSS
Ifremer–N. Reul/ESA SMOS+STORM project and REMSS
Taking this even further, measurements from two other satellites, NASA’s SMAP and Japan’s GCOM-W, which carry differing low-frequency microwave instruments, are being used with readings from SMOS to glean new information about surface winds under hurricanes.
Combining data from multiple satellites in this way provides a unique view of how the surface wind speed evolves under tropical storms in unprecedented detail.
This will greatly improve the information on the initial conditions of tropical cyclones fed into weather forecasting, and hence their prediction.
Scientists from Ifremer in France and the Met Office in the UK are assessing these new data and how they could be integrated into hurricane forecasting.
Measurements of sea-surface temperatures reveal cold-water wakes trailing the three recent hurricanes, highlighting the power these winds have in stirring the upper ocean and bringing cooler deep waters to the surface.
Changes in chlorophyll concentration
Ifremer–N. Reul/ESA SMOS+STORM project and REMSS
Interactions between the sea and atmosphere on this scale have implications for hurricane forecasting centres and for ocean forecasting systems such as Europe’s Copernicus Marine Environmental Monitoring Service.
Nicolas Reul from Ifremer said, “In addition to improving marine forecasting, the combination of data from sensors on different satellites will definitively enhance our understanding of ocean–atmosphere interactions in intense storms.
“Yet the future of this type of satellite measurement remains uncertain, as follow-on missions are not guaranteed.”
Craig Donlon, ESA’s ocean scientist, added, “Highlighting the societal benefits of new measurement approaches and Earth observation technologies is part of our core business.
“The exciting results emerging from this project demonstrate the importance of passive microwave sensors for extreme weather prediction and for understanding air–sea interactions, and the need to study future mission concepts that combine different microwave channels on a single satellite.”
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