For years, amateur aurora watchers from Canada have noticed mysterious streaks of pale purple and green light that seemed to dance across the nighttime sky. But it wasn’t until 2016 that they shared their colorful images with scientists, who soon identified the lightshow as a new type of upper-atmosphere phenomenon that was jokingly named STEVE. Additional contributions from citizen scientists are now helping researchers identify different types of STEVE emissions and constrain how, and where in Earth's atmosphere, they're generated.
"Scientists have known for several years that STEVE is not a regular type of aurora because it appears in lower latitudes and features different colors," said Xiangning Chu, a researcher at the Laboratory for Atmospheric and Space Physics at the University of Colorado Boulder. "But exactly how these light emissions form high in Earth's atmosphere remains a mystery."
STEVE, which was given the backronym Strong Thermal Emission Velocity Enhancement, typically appears as a narrow, purple band arching across the sky. This ribbon is sometimes accompanied by rippling green lights that look like a picket fence in photos. Because the purple and green lights don't always appear together, Chu wanted to determine whether the two lights share the same driver, but he wasn’t sure how to do this—until a lucky coincidence occurred on July 17, 2018.
That night, two citizen scientists located 400 kilometers (250 miles) apart snapped images of the same STEVE event. Because the photos were taken simultaneously from two different angles, Chu and his team were able to perform a simple triangulation, which provided them with the exact location of each point in the images.
The researchers then analyzed this information to try to resolve the location of STEVE’s driver. “We weren’t sure if we should be looking in part of the ionosphere, 100 to 400 kilometers above the Earth, or in the magnetosphere about 30,000 kilometers above the surface,” said Chu.
Researchers already knew that the green “pickets” follow Earth’s magnetic lines. What the analyses by Chu’s team show is that the purple and green emissions are located along the same magnetic field lines, though at different altitudes. Because they follow the same field lines across an extensive altitude range, Chu said there is no known local mechanism in the ionosphere that can account for them.
“Our analysis indicates that both the purple and green STEVE emissions are driven by the same, narrow region, so it must be the magnetosphere,” he said. “This supports our previous study, which provided evidence that STEVE’s driver region is located at a sharp boundary in the magnetosphere that’s marked by strong waves and particle acceleration.”
The coupling of the ionosphere and the magnetosphere is one of the fundamental topics in space physics, although this process is usually only considered at high latitudes, where auroras occur. But Chu said the results indicate that strong coupling might also occur at lower latitudes, transporting vast quantities of energy and momentum between the magnetosphere and ionosphere.
According to Chu, this research would not have been possible without the citizen scientists’ help. “I want to thank Neil Zeller and Colin Chatfield, who were so nice to provide their photographs for this analysis,” he said. “I encourage other citizen scientists to submit their images to the Alberta Aurora Chasers Facebook group.”
There are still many unresolved questions about STEVE, including how it’s generated, said Chu, and citizen scientists will likely continue to play an important role in this research.
“We are limited by the number of STEVE events and appropriate observations,” Chu sais. “This is a brand-new mechanism that has never been reported before. If we can solve this, we’ll have more information to add to our textbooks.”
Chu will present the team’s analysis on Wednesday, Dec. 15 at the American Geophysical Union Fall Meeting 2021. His co-authors include Lukas Wolter, David Malaspina, Laila Andersson, Martin Connors, Colin Chatfield and Neil Zeller.
LASP is at the forefront of solar and planetary research, climate and space-weather monitoring, and the search for evidence of habitable worlds. Our instruments and spacecraft, built in our state-of-the-art facilities at the University of Colorado Boulder, have visited every planet and Pluto and led to profound scientific discoveries. Every day, undergraduate and graduate students work alongside our scientists, mission operators, data analysts and engineers, as well as our many government, academic and industry partners, to push the limits of space science and exploration.