Throughout July 2023, NASA’s ER-2 aircraft flew close to thunderclouds to investigate lightning and its connection to the vast energy fields in our atmosphere. As the highest-flying plane of NASA’s Airborne Science Program, the ER-2 is giving researchers a new angle on storm clouds.
Historically, lightning has only been researched by low-flying aircraft or ground observers too far from thunderclouds to examine their detailed characteristics. Satellites like NASA’s TRMM (Tropical Rainfall Measurement Mission) and GOES (Geostationary Environmental Satellite), as well as the Lightning Imaging Sensor on the
NASA’s Armstrong Flight Research Center in Edwards, California collaborated with the University of Bergen, Norway to create the ALOFT project, Airborne Lightning Observatory for Fly’s eye simulator and Terrestrial gamma-ray flashes. The team included scientists and investigators from the University of Bergen, Norway, and pilots, engineers, and technicians from NASA who investigated lightning glows and terrestrial gamma-ray flashes. Flying just above the height of thunderclouds over the Floridian and Caribbean coastlines, NASA’s ER-2 aircraft collect more accurate data that can advance the study of high-energy radiation emissions from thunderstorms. Credit: NASA’s Armstrong Flight Research Center
The ALOFT Project: A Deeper Dive into Lightning Research
Scientists participating in the ALOFT project — Airborne Lightning Observatory for Fly’s Eye Simulator and Terrestrial Gamma Rays — have been using the ER-2 to fly above Central America, the Caribbean, and the coast of Florida, which are hotspots for thunderstorm activity at this time of year. From just above the height of a thundercloud, the team expects to collect detailed data that can advance the study of high-energy radiation emissions from thunderstorms. The field campaign includes instruments and researchers from the University of Birkeland in Norway, NASA’s Marshall Space Flight Center and Goddard Space Flight Center, Sandia National Labs, and the U.S. Naval Research Laboratory.
“This is a mission to go into the microphysics of what is going on in the enormous electric field above our heads,” said principal investigator Nikolai Ostgaard from the University of Birkeland. “Our goal is to understand how and under what conditions TGFs, or terrestrial gamma-ray flashes, are produced. We also aim to understand the behavior of gamma-ray glows in thunderclouds.”
Understanding the Science of Gamma Rays and Thunderclouds
The science underpinning these glows and flashes can be likened to a battery: a thundercloud is charged by the electric friction between humid air and cold air crystals, and that energy is discharged by lightning. Those discharges reduce the glow of extremely energetic photons — gamma rays — inside the thundercloud. Storm clouds can also produce gamma-ray flashes, which occur as brief bursts of light that last from tens to hundreds of a microsecond and are even more intense than gamma-ray glows.
“If you pass a thundercloud that is glowing in gamma rays, that means the electric field inside the cloud is very large,” said Ostgaard. The ALOFT science team is observing the gamma-ray activity of thunderclouds by examining this glow.
NASA pilots are flying the ER-2 as close to thunderclouds as safely possible to collect data with Instruments mounted on the aircraft. They measure the brightness of gamma rays (in photons per microsecond) by using scintillators – or crystals – that create a light pulse when hit by a gamma ray. A photomultiplier transforms these light pulses into electric pulses that indicate electrical charge. The ALOFT team on the ground receives this data in real-time, and if they detect that the aircraft is flying near an electrically glowing thundercloud, they instruct the pilot to circle and fly over that cell as long as possible.
Supplementary Instruments and Future Insights
In addition to the lightning instrumentation, NASA is providing additional measurements from precipitation and cloud radars and microwave radiometers. These additional instruments provide the ability to measure the structures and microphysical properties of storms, which can provide further insight into the mechanisms behind the electric fields.
“Our instruments are designed with a very high time resolution, so we can see a
Ostgaard is excited about what new insights this data will reveal about lightning and the electric field above us. “It will open doors to understanding lightning because we do not really understand how these gamma-ray flashes and glows are related to thunderclouds and lightning,” he said. The information gathered will also help scientists and engineers evaluate new design concepts for the next generation of space-based lightning mappers.