Terrestrial Gamma-ray Flashes Create Antimatter

TGFs produce high-energy electrons and positrons. Moving near the speed of light, these particles travel into space along Earth's magnetic field.

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Interactions with matter can produce gamma rays and vice versa. So-called "bremsstrahlung" gamma rays result when high-energy electrons traveling close to the speed of light become deflected by passing near an atom or molecule. In pair production, a gamma ray passing through the electron shell of an atom transforms into two particles: an electron and its antimatter opposite, a positron.

Animated diagram showing the behavior and composition of TGF emissions.

Credit: NASA/Goddard Space Flight Center/J. Dwyer/Florida Inst. of Technology

A TGF produces gamma rays (magenta) as well as high-energy electrons (yellow) and positrons (green). This simulation tracks a TGF and its particle beams from their origin altitude of 9.3 miles (15 km) to 373 miles (600 km), beyond Fermi's orbit.

Credit: Joe Dwyer/Florida Inst. of Technology

Sidebar: How thunderstorms launch particle beams into space

On Dec. 14, 2009, while NASA's Fermi flew over Egypt, the spacecraft intercepted a particle beam from a terrestrial gamma-ray flash (TGF) that occurred over its horizon. Fermi's Gamma-ray Burst Monitor detected the signal of positrons annihilating on the spacecraft — not once, but twice. After passing Fermi, some of the particles reflected off of a magnetic "mirror" point and returned.

On Dec. 14, 2009, while NASA's Fermi flew over Egypt, the spacecraft intercepted a particle beam from a terrestrial gamma-ray flash (TGF) that occurred over its horizon. Fermi's Gamma-ray Burst Monitor detected the signal of positrons annihilating on the spacecraft — not once, but twice. After passing Fermi, some of the particles reflected off of a magnetic "mirror" point and returned. No Labels.

Fermi's position relative to the TGF it detected.

Artist interpretation of the cloud of electrons and positrons passing through the Fermi satellite and causing it to emit gamma rays.

Artist interpretation of electrons accelerating upwards from a thunderhead.

Map of all terrestrial gamma-ray flashes detected by Fermi's Gamma-ray Burst Monitor through the end of 2010.

For animated version, go here,

This image from the Meteosat 9 weather satellite was taken on Dec. 14, 2009, about 7 minutes after Fermi detected positrons from a TGF. No storms are present over Egypt, where Fermi was located at the time of the event, but thunderstorms are plentiful over Zambia.

Credit: SSEC/Univ. of Wisconsin, Madison