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The solar wind is swirly

In the stream of charged particles emitted by the Sun, turbulence is thought to play a key part in maintaining its heat as it streams away and races across the solar system.
Solar-wind
A 2-D vision of the solar wind turbulence at the smallest scale seen yet, thanks to observations by Cluster satellites. The approximate location of the measurements are indicated on a graphic illustrating features of Earth’s magnetic environment. The inset shows conditions as would be seen facing the solar wind, with current sheets forming at the border of turbulent eddies. The trajectory of the Cluster spacecraft is marked on the inset by the black line and the color gradients represent the magnetic field strength intensity from 4.8 nT (darkest shades) to 5.2 nT (white). // Credit: ESA
Using the European Space Agency’s (ESA) Cluster quartet of satellites as a space plasma microscope, scientists have zoomed in on the solar wind to reveal the finest detail yet, finding tiny turbulent swirls that could play a big role in heating it.

Turbulence is highly complex and all around us, evident in water flowing from a tap, around an aircraft wing, in experimental fusion reactors on Earth, and also in space.

In the stream of charged particles emitted by the Sun — the solar wind — turbulence is thought to play a key part in maintaining its heat as it streams away and races across the solar system.

As the solar wind expands, it cools down, but to a much smaller extent than would be expected if the flow were smooth.

Turbulence arises from irregularities in the flow of particles and magnetic field lines, but understanding how this energy is transferred from the large scales where it originates to the small scales where it is dissipated is like trying to trace energy as it is transferred from the smooth, laminar flow of a river down to the small turbulent eddies formed at the bottom of a waterfall.

In a new study, two of the four Cluster satellites have made extremely detailed observations of plasma turbulence in the solar wind. They were separated by just 12 miles (20 kilometers) along the direction of the plasma flow and operated in “burst mode” to take 450 measurements per second.

By comparing the results with computer simulations, scientists confirmed the existence of sheets of electric current just 12 miles (20km) across on the borders of turbulent swirls.

“This shows for the first time that the solar wind plasma is extremely structured at this high resolution,” said Silvia Perri from the University of Calabria in Italy.

Cluster previously detected current sheets on much larger scales of 62 miles (100km) in the magnetosheath, the region sandwiched between Earth’s magnetic bubble — the magnetosphere — and the bow shock that is created as it meets the solar wind.

At the borders of these turbulent eddies, the process of “magnetic reconnection” was detected, whereby oppositely directed field lines spontaneously break and reconnect with other nearby field lines, thus releasing their energy.

“Although we haven’t yet detected reconnection occurring at these new smaller scales, it is clear that we are seeing a cascade of energy which may contribute to the overall heating of the solar wind,” said Perri.

Future missions such as ESA’s Solar Orbiter and NASA’s Solar Probe Plus will be able to determine whether similar processes are also in play closer to the Sun, while NASA’s Magnetospheric Multiscale mission will specifically probe the small-scale regions where reconnection can occur.

“This Cluster result demonstrates the mission’s unique capability to probe universal physical phenomena, in this case pushing the mission’s instrument measurement capabilities to their limit to unlock features at small scales,” said Matt Taylor from ESA.

“Future multi-spacecraft missions will make very detailed studies of these small-scale plasma phenomena and provide further context to our Cluster measurements.”

Using the European Space Agency’s (ESA) Cluster quartet of satellites as a space plasma microscope, scientists have zoomed in on the solar wind to reveal the finest detail yet, finding tiny turbulent swirls that could play a big role in heating it.

Turbulence is highly complex and all around us, evident in water flowing from a tap, around an aircraft wing, in experimental fusion reactors on Earth, and also in space.

In the stream of charged particles emitted by the Sun — the solar wind — turbulence is thought to play a key part in maintaining its heat as it streams away and races across the solar system.

As the solar wind expands, it cools down, but to a much smaller extent than would be expected if the flow were smooth.

Turbulence arises from irregularities in the flow of particles and magnetic field lines, but understanding how this energy is transferred from the large scales where it originates to the small scales where it is dissipated is like trying to trace energy as it is transferred from the smooth, laminar flow of a river down to the small turbulent eddies formed at the bottom of a waterfall.

In a new study, two of the four Cluster satellites have made extremely detailed observations of plasma turbulence in the solar wind. They were separated by just 12 miles (20 kilometers) along the direction of the plasma flow and operated in “burst mode” to take 450 measurements per second.

By comparing the results with computer simulations, scientists confirmed the existence of sheets of electric current just 12 miles (20km) across on the borders of turbulent swirls.

“This shows for the first time that the solar wind plasma is extremely structured at this high resolution,” said Silvia Perri from the University of Calabria in Italy.

Cluster previously detected current sheets on much larger scales of 62 miles (100km) in the magnetosheath, the region sandwiched between Earth’s magnetic bubble — the magnetosphere — and the bow shock that is created as it meets the solar wind.

At the borders of these turbulent eddies, the process of “magnetic reconnection” was detected, whereby oppositely directed field lines spontaneously break and reconnect with other nearby field lines, thus releasing their energy.

“Although we haven’t yet detected reconnection occurring at these new smaller scales, it is clear that we are seeing a cascade of energy which may contribute to the overall heating of the solar wind,” said Perri.

Future missions such as ESA’s Solar Orbiter and NASA’s Solar Probe Plus will be able to determine whether similar processes are also in play closer to the Sun, while NASA’s Magnetospheric Multiscale mission will specifically probe the small-scale regions where reconnection can occur.

“This Cluster result demonstrates the mission’s unique capability to probe universal physical phenomena, in this case pushing the mission’s instrument measurement capabilities to their limit to unlock features at small scales,” said Matt Taylor from ESA.

“Future multi-spacecraft missions will make very detailed studies of these small-scale plasma phenomena and provide further context to our Cluster measurements.”

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