miércoles, 1 de agosto de 2018

Planetary Defense Has New Tool in Weather Satellite Lightning Detector | NASA

Planetary Defense Has New Tool in Weather Satellite Lightning Detector | NASA



A bright meteor in Earth’s atmosphere appears as a white spot off the north coast of South America.

Planetary Defense Has 

New Tool in Weather 

Satellite Lightning Detector

A meteor appears in a satellite image of Earth as a white spot over the ocean.
On December 29, 2017, the Geostationary Lightning Mapper, an instrument flying on board two weather satellites, detected a bright meteor in Earth’s atmosphere over the western Atlantic Ocean.
Credits: NASA/Lockheed Martin
NASA's efforts to better understand asteroid impacts has found unexpected support from a new satellite sensor designed to detect lightning. New research published in the journal Meteoritics and Planetary Science finds that the new Geostationary Lightning Mapper, or GLM, on two weather satellites is able to pick up signals of meteors in Earth's atmosphere.
Data image from a satellite sensor shows one moment of a December 2017 meteor event.
The bright flash produced by the December 2017 meteor was picked up by the Geostationary Lightning Mapper. This image shows one moment of that meteor event, which released three kilotons of energy into the atmosphere. In the image inset, red represents the bright meteor, while blue indicates the faint light reflected off the ocean surface and the signal caused by the instrument recovering from the bright exposure.
Credits: NASA/Lockheed Martin
"GLM detects these meteors when they become brighter than the full Moon," says lead author and meteor astronomer Peter Jenniskens of the SETI Institute and NASA’s Ames Research Center in California’s Silicon Valley. "Meteors that bright are called 'bolides' and they are caused mainly by the impact of small asteroids."
Slow-motion movie of a bright meteor, showing how individual GLM sensor pixels are illuminated in successive frames.
Slow-motion movie of the December 2017 meteor impacting Earth's atmosphere. Individual pixels in the Geostationary Lightning Mapper's sensor are illuminated in successive frames.
Credits: NASA/Lockheed Martin
Jenniskens' work on meteors contributes to the NASA Ames Asteroid Threat Assessment Program, which helps improve information for impact prediction warnings by studying how asteroids fragment as they travel through the atmosphere.
"The range of altitudes over which asteroids deposit their kinetic energy — the energy of their motion — determines how dangerous the shock waves are that can cause damage on the ground," says Eric Stern, a research scientist at Ames who is the entry modeling lead for the program. "The light profiles derived from GLM data are slated now to be used in a future version of NASA’s automated bolide reporting system."
The Geostationary Lightning Mapper, built by Lockheed Martin, was designed for mapping lightning flashes over vast geographic regions. The instrument captures 500 images per second of Earth from geostationary orbit, in which the satellite is always in the same position with respect to the rotating Earth, more than 22,000 miles up.
"The instrument views Earth in only a narrow range of wavelengths of light," said Samantha Edgington, GLM chief scientist at Lockheed Martin, who led the effort to develop the processing pipeline that now provides lightning data to weather forecasters. "Since most of the light is blocked, we were surprised to see how readily the instrument detected the meteors."
GLM is one of several instruments onboard the new Geostationary Operational Environmental Satellites-16 and -17, which are operated by the National Atmospheric and Oceanic Administration.
"Although most lightning flashes are very brief, the relatively long-duration signals of bolides are not filtered out of the data," said NOAA physical scientist Scott Rudlosky. "That’s because GLM also was designed to measure a longer-lasting lightning type that is known to play a key role in lightning-ignited wild fires."
The ten bolides discussed in the paper were observed with the first GLM instrument on board GOES-16, which was launched in November 2016.
"The first bolide we found in GLM data was on Feb. 6, 2017; more than 500 people reported seeing this event over Wisconsin that day," said Jenniskens. "Meteorites likely fell in Lake Michigan but were never recovered."
Other detected bolides show different manners of fragmentation. They include one that caused a meteorite fall in Canada and another large, explosive event over the western Atlantic Ocean of a rare size that occurs only once a year.
The Asteroid Threat Assessment Program is funded by the NASA Planetary Defense Coordination Office. The scientific paper is available online in the journal Meteoritics and Planetary Science.
Last Updated: Aug. 1, 2018
Editor: Abigail Tabor

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