Compressive fluctuations heat ions in space plasma

December 18, 2020

New simulations carried out in part on the ATERUI II supercomputer in Japan have found that the reason ions exist at higher temperatures than electrons in space plasma is because they are better able to absorb energy from compressive turbulent fluctuations in the plasma. These finding have important implications for understanding observations of various astronomical objects such as the images of the accretion disk and shadow of the M87 supermassive black hole captured by the Event Horizon Telescope.

In addition to the normal three states of matter (solid, liquid, and gas) which we see around us every day, there is an additional state called plasma which exists only at high temperatures. Under these conditions, electrons become separated from their parent atoms leaving behind positively charged ions. In space plasma the electrons and ions rarely collide with each other, meaning that they can coexist in different conditions, such as at different temperatures. However, there is no obvious reason why they should have different temperatures unless some force affects them differently. So why ions are usually hotter than electrons in space plasma has long been a mystery.

One way to heat plasma is by turbulence. Chaotic fluctuations in turbulence smoothly mix with particles, and then their energy is converted into heat. To determine the roles of different types of fluctuations in plasma heating, an international team led by Yohei Kawazura at Tohoku University in Japan performed the world's first simulations of space plasma including two types of fluctuations, transverse oscillations of magnetic field lines and longitudinal oscillations of pressure. They used nonlinear hybrid gyrokinetic simulations which are particularly good at modeling slow fluctuations. These simulations were conducted on several supercomputers, including ATERUI II at the National Astronomical Observatory of Japan.

The results showed that the longitudinal fluctuations like to mix with ions but leave electrons. On the other hand the transverse fluctuations can mix with both ions and electrons. "Surprisingly, the longitudinal fluctuations are picky about the partner species to mix with," says Kawazura. This is a key result for understanding the ion to electron heating ratios in plasmas observed in space, like that around the supermassive black hole in Galaxy M87.
These results appeared as Y. Kawazura et al. "Ion versus Electron Heating in Compressively Driven Astrophysical Gyrokinetic Turbulence" in Physical Review X, on December 11, 2020.

National Institutes of Natural Sciences

Related Plasma Articles from Brightsurf:

Plasma treatments quickly kill coronavirus on surfaces
Researchers from UCLA believe using plasma could promise a significant breakthrough in the fight against the spread of COVID-19.

Fighting pandemics with plasma
Scientists have long known that ionized gases can kill pathogenic bacteria, viruses, and some fungi.

Topological waves may help in understanding plasma systems
A research team has predicted the presence of 'topologically protected' electromagnetic waves that propagate on the surface of plasmas, which may help in designing new plasma systems like fusion reactors.

Plasma electrons can be used to produce metallic films
Computers, mobile phones and all other electronic devices contain thousands of transistors, linked together by thin films of metal.

Plasma-driven biocatalysis
Compared with traditional chemical methods, enzyme catalysis has numerous advantages.

How bacteria protect themselves from plasma treatment
Considering the ever-growing percentage of bacteria that are resistant to antibiotics, interest in medical use of plasma is increasing.

A breakthrough in the study of laser/plasma interactions
Researchers from Lawrence Berkeley National Laboratory and CEA Saclay have developed a particle-in-cell simulation tool that is enabling cutting-edge simulations of laser/plasma coupling mechanisms.

Researchers turn liquid metal into a plasma
For the first time, researchers at the University of Rochester's Laboratory for Laser Energetics (LLE) have found a way to turn a liquid metal into a plasma and to observe the temperature where a liquid under high-density conditions crosses over to a plasma state.

How black holes power plasma jets
Cosmic robbery powers the jets streaming from a black hole, new simulations reveal.

Give it the plasma treatment: strong adhesion without adhesives
A Japanese research team at Osaka University used plasma treatment to make fluoropolymers and silicone resin adhere without any adhesives.

Read More: Plasma News and Plasma Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to