The energy comes directly from the sun’s corona, a blazing hot environment that shoots particles out in all directions at speeds around 1 million miles per hour. This is the forceful solar wind. When its power hits the magnetosheath, waves of plasma chaos roll through it.

Scientists don’t know yet how all of that turbulent energy is dissipated. But this new discovery—electron magnetic reconnection—may help them learn more.

The MMS mission has four spacecraft flying in formation about four miles apart, gathering data as they go. Its array of instruments gave researchers one of their first opportunities to search for reconnection in the magnetosheath.

They got what they hoped to get—evidence that magnetic reconnection was happening even in that chaotic turbulence. But in the process, they discovered magnetic reconnection here works much differently than the kind observed elsewhere. Instead of huge jets of ionized hydrogen atoms, triggered by many collisions of magnetic fields, this form of magnetic reconnection shoots off much tinier electron jets with very few collisions occurring, Shay said.

This has never been recognized before, partly because no instruments could capture the process.

The relative difference in size between the electrons and the ions is similar to the difference between ball bearings and basketballs, Shay said. The electrons are harder to spot. And they are moving much faster—40 times faster, he said.

“I had simulated this possible kind of reconnection,” Shay said. “But no one had ever observed it happening in space.”

The magnetosheath reconnection was too fast and too tiny for the MMS instruments to capture in the usual way, but researchers developed a new way of using one of the instruments—the Fast Plasma Investigation—that gave them the perspective they needed to see what was going on.

“The key event of the paper happens in 45 milliseconds,” said Amy Rager, a graduate student at Catholic University of America in Washington, D.C., who worked on the technique at NASA’s Goddard Space Flight Center. “This would be one data point with the regular data, but instead we can get six to seven data points in that region with this method, allowing us to understand what is happening.”

Also among the co-authors of the paper were two members of Shay’s research group—postdoctoral researcher Colby Haggerty and graduate student Prayash Sharma Pyakurel.

The analysis could reveal many more surprises as scientists continue to explore the data MMS has sent.

“MMS has taken us to a whole new level,” Shay said. “It’s like knowing about atoms and then finding out about even tinier parts like the nucleus or the electrons. People were not expecting it.”