The improved detection is also giving scientists a better idea of what causes the perplexing phenomenon.
The high-energy outbursts that occur above thunderstorms are known as(TGFs) and they last only a few thousandths of a second. But even in that brief flash, they rank among the highest-energy forms of light that occur naturally on Earth, according to a NASA release.
TGFs are detected from orbit by the Gamma-ray Burst Monitor (GBM) aboard , which was recently upgraded and is now 10 times better at catching the phenomenon.
Previously, the GBM only detected the brightest flashes, which would trigger its on-board system.
"In mid-2010, we began testing a mode where the GBM directly downloads full-resolution gamma-ray data even when there is no on-board trigger, and this allowed us to locate many faint TGFs we had been missing," said lead researcher Valerie Connaughton, a member of the GBM team at the University of Alabama in Huntsville (UAH).
The satellite spotted 601 TGFs between August 2008 and August 2011, with 409 of those coming from the use of the new technique.
The results of the trial, presented last week at the annual meeting of the American Geophysical Union in San Francisco, were so impressive that the team uploaded new software onto the satellite on Nov. 26 that would keep the instrument operating in the new mode continuously. With the new mode online, the team estimates they will catch about 850 TGFs each year, NASA said, though that is only a fraction of the 1,100 TGFs the team estimates occur each day. 
To learn more about what causes the gamma-ray flashes, the GBM team compared the new TGF data with signals of very low frequency (VLF) radio waves emitted by lightning (this is often heard as popping and crackling on an AM radio).
Scientists had thought that the radio waves were emitted by strokes of lightning that were themselves somehow associated with the TGFs, according to the NASA release, but the GBM comparison found that the radio emissions occurred nearly simultaneously with the TGF, said team member Michael Briggs.
The TGFs are thought to be generated by strong electrical fields at the . Certain conditions cause the fields to become strong enough that they send a rush of electrons upward, which then interact with air molecules and give off the gamma rays. That rush could also be the source of the radio emissions.
"This gives us a new window into understanding this phenomenon," study team member Joseph Dwyer, a physics professor at the Florida Institute of Technology in Melbourne, Fla., said in a statement.
The team hopes to use this relationship, along with new data from Fermi and lightning radio signals observed from Earth, to get a clearer picture ofand what kinds of storms produce them.
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