Doppler measurements that help track storms on Earth may also be useful for understanding storms on the sun.
Left, image of hot (1.8-million degree Fahrenheit) active region loops. Right, flows of solar plasma (blue shifts). Credit: SDO/AIA (NASA and Hinode/EIS (JAXA, NASA, ESA and STFC)
A Rice University astrophysicist is part of an international team that combined Doppler techniques with images and data from a space-based telescope to observe, for the first time, loops of 1,800,000-degree Fahrenheit plasma flowing up from the sun’s surface at more than 12 miles per second.
The loops, rooted in active regions near sunspots and guided by the sun’s magnetic field, arch over the sun and may be the first signs of trouble spots, where plasma undergoes “impulsive heating,” according to the researchers. They expect their findings will help scientists understand the genesis of solar flares and coronal mass ejections – solar storms – that threaten satellites orbiting Earth and power transmission grids on the ground.
Rice’s Stephen Bradshaw and colleagues in India and the United Kingdom reported their results today in the Astrophysical Journal Letters.
They wrote that Doppler measurements drawn from images taken by the Extreme-ultraviolet Imaging Spectrometer (EIS) aboard the Hinode solar satellite show the first observation of a “warm loop” in which plasma rises from the surface of the sun rather than sinks back into it.
In visible-light Doppler, objects moving away from the viewer are shifted red, while objects moving closer shift blue. That fact has long been useful to astrophysicists judging how fast other stars and even galaxies are moving in an expanding universe. But in previous observations of active regions on the sun, warm loops like the one observed by Bradshaw and his colleagues have only been seen to shift red and, therefore, the plasma was thought to be sinking.
The prevalence of red shifts led to the belief that heating is taking place high in the sun’s atmosphere and leading to the evaporation of material from near the surface into the atmosphere that then flows back down as it cools. That may be true, Bradshaw said, but it leaves some important questions unanswered: What causes the heating? Where is the evidence for plasma rising from the surface into the atmosphere?
The new observations will help to answer these questions, he said.
“The blue shifts are the signature, or ‘smoking gun,’ of plasma flowing up into the atmosphere,” said Bradshaw, Rice’s William V. Vietti Junior Chair of Space Physics and an assistant professor of physics and astronomy. “They show that the fastest up-flows are found near the surface of the sun. This information gives us clues to the location where the heating is taking place, how fast it is and how much energy is needed.”
“The Sun governs the environment in which we live, and it is the so-called solar active regions that drive extreme conditions leading to the explosive flares and the huge eruptions; understanding these active regions is absolutely critical for the study of what we now call space weather,” said Richard Harrison, head of space physics and chief scientist at the Rutherford Appleton Laboratory in the United Kingdom. “The work published in this paper is a key element of that work, applying innovative analyses to the observations from the U.K.-led Hinode/EIS instrument.”
Bradshaw noted the sun is fast approaching the part of its 11-year cycle when flares and coronal mass ejections occur most frequently. “These events present the most danger to satellites, power grids and even to airliners on flight paths in polar regions,” Bradshaw said. “This period is called solar maximum, and we will become ever more reliant on this technology during every subsequent solar cycle.
“One of the aims of solar research is to develop a space-weather forecasting capability, whereby solar storms can be predicted by detecting their signatures before they occur at the sun,” he said. “This is much like monitoring depressions as precursors to tropical storms and hurricanes, but space-weather forecasters will monitor active regions. Accurate forecasts of solar storms will give us the maximum possible time to prepare for their arrival at Earth and to mitigate their effects.
“Our work will contribute to this aim by leading to a better understanding of the physics of active regions.”
Source: Rice University