New experiments reveal the source of the aurora borealis
[May 2, 2022: Michael Church, DOE/US Department of Energy]
New experiments have shown the source of the aurora borealis. (CREDIT: Shutterstock)
New experiments have shown the source of the aurora borealis. Researchers have demonstrated Alfvén waves accelerating electrons under conditions that correspond to Earth’s magnetosphere.
The magnetosphere around the Earth contains ionized charged particles or plasma, one of the four types of matter along with solid, liquid, and gas. Plasmas are similar to both fluids and gases but also contain magnetic and electric fields. In 1942, Hannes Alfvén predicted that plasmas could support waves. These waves are today called Alfvén waves.
The new experiments show that electrons “surf” on the electric field of the Alfvén wave in a phenomenon known as Landau damping. This means the energy of the wave is transferred to the accelerated electrons, like a surfer catching a wave and being continually accelerated as the surfer moves along with the wave. These electrons are the ultimate source of the light we call the aurora borealis.
The shimmering displays of the aurora borealis have always fascinated humanity. Now scientists have demonstrated how electrons associated with the aurora accelerate towards the Earth, where they collide with molecules in the upper atmosphere. These collisions cause the emission of auroral light.
The new research reproduced the conditions in space above the aurora in the laboratory. It shows that Alfvén waves launched by storms in the earth’s magnetic field can accelerate the electrons that cause the bright glow of the aurora. These results definitively confirm this previously unproven hypothesis.
As electrons accelerated by Alfvén waves stream along the Earth's magnetic field (yellow drops), they collide with oxygen atoms (white dots) and molecules of oxygen and nitrogen (white dumbbells) and cause them to emit light and create the auroras. (CREDIT: Austin Montelius, College of Liberal Arts and Sciences, University of Iowa)
The spectacular displays of the aurora borealis have always fascinated humankind. More recently, they have captured the attention of scientists curious to explain this phenomenon.
Scientists know that electrons from space precipitate into the upper atmosphere and collide with atoms and molecules to produce auroral light. The cause of this electron precipitation has been an area of ongoing research.
One theory is supported by the fact that scientists regularly find powerful electromagnetic waves called Alfvén waves traveling toward the Earth above auroras. According to this theory, Alfvén waves accelerate electrons toward Earth, causing them to precipitate and produce auroras.
Although space-based measurements provide strong support of this theory, the limitations of these measurements have prevented a definitive test. To overcome these limitations, researchers performed laboratory experiments on the Large Plasma Device (LAPD) at University of California, Los Angeles (UCLA) Basic Plasma Science Facility, a national collaborative research facility supported jointly by the Department of Energy and the National Science Foundation.
In a laboratory experiment that reproduced the conditions in Earth's magnetosphere, the team launched Alfvén waves down the LAPD chamber and then measured the electrons accelerated by the electric field of the Alfvén waves. Measurements revealed these particular electrons undergo resonant acceleration by the wave's electric field, similar to a surfer catching a wave and being continually accelerated by the wave. This phenomenon of the energy of a wave transferring to accelerated electrons is known as Landau damping.
The research team combines the measurements of the wave's electric field and the electrons to generate a unique signature of the electron acceleration by Landau damping. Through simulations and modeling, they showed that the signature of acceleration measured in the experiment agreed with the predicted signature for Landau damping.
The agreement of experiment, simulation, and modeling provides the first direct test showing that Alfvén waves can produce accelerated electrons that cause the aurora.
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Note: Materials provided above by DOE/US Department of Energy. Content may be edited for style and length.
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