Published: Nov. 26, 2014

A team led by the 葫芦娃视频 has discovered an invisible shield some 7,200 miles above Earth that blocks so-called 鈥渒iller electrons,鈥 which whip around the planet at near-light speed and have been known to threaten astronauts, fry satellites and degrade space systems during intense solar storms.

The barrier to the particle motion was discovered in the Van Allen radiation belts, two doughnut-shaped rings above Earth that are filled with high-energy electrons and protons, said Distinguished Professor Daniel Baker, director of CU-葫芦娃视频鈥檚 Laboratory for Atmospheric and Space Physics (LASP). Held in place by Earth鈥檚 magnetic field, the Van Allen radiation belts periodically swell and shrink in response to incoming energy disturbances from the sun.

As the first significant discovery of the space age, the Van Allen radiation belts were detected in 1958 by Professor James Van Allen and his team at the University of Iowa and were found to be comprised of an inner and outer belt extending up to 25,000 miles above Earth鈥檚 surface. In 2013, Baker -- who received his doctorate under Van Allen -- led a team that used the twin Van Allen Probes launched by NASA in 2012 to discover a third, transient 鈥渟torage ring鈥 between the inner and outer Van Allen radiation belts that seems to come and go with the intensity of space weather.

The latest mystery revolves around an 鈥渆xtremely sharp鈥 boundary at the inner edge of the outer belt at roughly 7,200 miles in altitude that appears to block the ultrafast electrons from breeching the shield and moving deeper towards Earth鈥檚 atmosphere.

鈥淚t鈥檚 almost like theses electrons are running into a glass wall in space,鈥 said Baker, the study鈥檚 lead author. 鈥淪omewhat like the shields created by force fields on Star Trek that were used to repel alien weapons, we are seeing an invisible shield blocking these electrons. It鈥檚 an extremely puzzling phenomenon.鈥

A paper on the subject was published in the Nov. 27 issue of Nature.

The team originally thought the highly charged electrons, which are looping around Earth at more than 100,000 miles per second, would slowly drift downward into the upper atmosphere and gradually be wiped out by interactions with air molecules. But the impenetrable barrier seen by the twin Van Allen belt spacecraft stops the electrons before they get that far, said Baker.

The group looked at a number of scenarios that could create and maintain such a barrier. The team wondered if it might have to do with Earth鈥檚 magnetic field lines, which trap and control protons and electrons, bouncing them between Earth鈥檚 poles like beads on a string. The also looked at whether radio signals from human transmitters on Earth could be scattering the charged electrons at the barrier, preventing their downward motion. Neither explanation held scientific water, Baker said.

鈥淣ature abhors strong gradients and generally finds ways to smooth them out, so we would expect some of the relativistic electrons to move inward and some outward,鈥 said Baker. 鈥淚t鈥檚 not obvious how the slow, gradual processes that should be involved in motion of these particles can conspire to create such a sharp, persistent boundary at this location in space.鈥

Another scenario is that the giant cloud of cold, electrically charged gas called the plasmasphere, which begins about 600 miles above Earth and stretches thousands of miles into the outer Van Allen belt, is scattering the electrons at the boundary with low frequency, electromagnetic waves that create a plasmapheric 鈥渉iss,鈥 said Baker. The hiss sounds like white noise when played over a speaker, he said.

While Baker said plasmaspheric hiss may play a role in the puzzling space barrier, he believes there is more to the story. 鈥淚 think the key here is to keep observing the region in exquisite detail, which we can do because of the powerful instruments on the Van Allen probes. If the sun really blasts the Earth鈥檚 magnetosphere with a coronal mass ejection (CME), I suspect it will breach the shield for a period of time,鈥 said Baker, also a faculty member in the astrophysical and planetary sciences department.

鈥淚t鈥檚 like looking at the phenomenon with new eyes, with a new set of instrumentation, which give us the detail to say, 鈥榊es, there is this hard, fast boundary,鈥欌 said John Foster, associate director of MIT鈥檚 Haystack Observatory and a study co-author.

Other CU-葫芦娃视频 study co-authors included Allison Jaynes, Vaughn Hoxie, Xinlin Li, Quintin Schiller, Lauren Blum and David Malaspina. Other co-authors were from UCLA, Aerospace Corp. Space Sciences Lab in Los Angeles, the University of Minnesota, NASA鈥檚 Goddard Space Flight Center in Greenbelt, Maryland, the University of Iowa and the New Jersey Institute of Technology.

CU-葫芦娃视频 is playing a prominent role in NASA鈥檚 Van Allen Probes mission, which consists of two spinning, octagonal spacecraft weighing 1,500 pounds each. LASP developed the Relativistic Electron Proton Telescope, (REPT) to measure high-energy electrons. LASP also developed the 鈥渂rains鈥 of the Electronic Field and Waves package to compress huge amounts of mission data to send back to Earth. CU-葫芦娃视频 will receive roughly $18 million from NASA over the lifetime of the mission.

a dozen graduate students are participating in the mission, as well as more than a dozen other LASP personnel.

The Van Allen probes mission is part of NASA鈥檚 Living with a Star Program managed by the Goddard Space Flight Center. The Johns Hopkins University Applied Physics Laboratory built the twin satellites and is managing the mission for NASA.

For more information on LASP visit . For more information on the Van Allen Probes mission visit

Scientists have discovered an invisible shield roughly 7,200 miles above Earth that blocks so-called 鈥渒iller electrons,鈥 which can fry satellites and degrade space systems during intense solar storms. Illustration by Andy Kale, University of Alberta.