New patterns in Sun鈥檚 layers could help scientists solve solar mystery

Astronomers are one step closer to understanding one of the most enduring solar mysteries, having captured unprecedented data from the Sun鈥檚 magnetic field.

An image of the 'quiet' side of the sun.
Small-scale magnetic structures of the 鈥榪uiet Sun鈥 at high resolution captured by DKIST. Credit: Queen's University Belfast
  • New research from an international team may explain one of the biggest conundrums in astrophysics 鈥 why the outermost layer of the Sun鈥檚 atmosphere is hotter than the surface
  • Groundbreaking data collected from the world's most powerful solar telescopes shows a snake-like pattern in the Sun鈥檚 magnetic fields that could contribute to the heating of the Sun鈥檚 outermost atmosphere
  • The project, which includes scientists across a wide range of institutions on both sides of the Atlantic ocean, has opened new avenues in solar physics

Astronomers are one step closer to understanding one of the most enduring solar mysteries, having captured unprecedented data from the Sun鈥檚 magnetic field.

The groundbreaking data collected from the US National Science Foundation's (NSF) Daniel K Inouye Solar Telescope (DKIST) in Hawaii - the most powerful solar telescope in the world - has provided the most detailed representations to date of the magnetic field of the so-called 鈥榪uiet鈥 surface of the Sun.

An international team of scientists, including researchers from the University of 葫芦影业, believe the data has implications for how we model energy transfer between the layers of the Sun.

This might help explain one of the biggest conundrums in astrophysics 鈥 why the outermost layer of the Sun (鈥榗orona鈥) is hundreds of times hotter than the surface (鈥榩hotosphere鈥), even though the opposite would be expected.

Professor Robertus Erdelyi, a senior co-investigator from the University of 葫芦影业鈥檚 School of Mathematics and Statistics, said: 鈥淭he observations have revealed and confirmed a serpentine topology of the magnetic field in the lower solar atmosphere, often also called the chromosphere. An accurate insight into the magnetic field geometry is fundamental for the understanding of the various energetic phenomena that drive the dynamics of the plasma in the solar atmosphere.

鈥淭hat includes the much sought after magnetic behaviour that may ultimately be responsible for energising the solar plasma to temperatures of millions of Kelvins. These magnetic fields are also believed to drive the largest and most powerful explosions in our entire Solar System, the Coronal Mass Ejections (CMEs). 鈥

Inaugurated in 2022, DKIST is the most powerful, solar, optical telescope on Earth. It enables record-breaking observations of the Sun, with a resolving power being the equivalent to seeing a 50p coin in Manchester from London. 

The project led by Queen鈥檚 University Belfast in collaboration with the University of 葫芦影业, the NSF's National Solar Observatory, the High Altitude Observatory at California State University, the Max Planck Institute for Solar System Research in Germany and Eo虉tvo虉s Lora虂nd University in Hungary, harnessed this power to reveal a new, complex, snake-like pattern of energy in the magnetic field.

In the past, much research into the heat variations between the corona and photosphere has focused on 鈥榮unspots鈥 鈥 very large, highly magnetic and active regions, often comparable to Earth in size 鈥 that can act as conduits for energy between the Sun鈥檚 outer layers.

Away from sunspots, the so-called 鈥榪uiet sun鈥 is covered in convective cells known as 鈥榞ranules鈥, typically about the size of France, that harbour much weaker, but more dynamic magnetic fields that may hold the secrets to balancing the energy budget of the chromosphere.

Most observational reports of the past decade have found that magnetic fields are organised in terms of small loops in the quiet photosphere. With DKIST, researchers have detected something unexpected, finding the first evidence for a more complicated pattern consistent with a snake-like variation in the magnetic orientation.

Professor Michail Mathioudakis, Co-Investigator on the research and Director of ARC at Queen鈥檚 said: 鈥淭he more complex the small-scale variations in magnetic-field direction, the more plausible it is that energy is being released through a process we call magnetic reconnection 鈥 when two magnetic fields pointing in opposite directions interact and release energy that contributes to atmospheric heating.

鈥淲e have used the most powerful solar optical telescope in the world to reveal the most complex magnetic-field orientations ever seen at the smallest scales. This brings us closer to understanding one of the biggest conundrums in solar research."

Professor Erdelyi added: 鈥淭hanks to this research we may be one step closer in comprehending the Sun, our life-giving star.

"These are fantastic results achieved by a combination of junior and senior scientists across a wide range of institutions at both sides of the Atlantic ocean. The DKIST solar telescope, the largest of its kind, has opened revolutionary new avenues in solar physics.鈥

The research has been published in and was supported by research funding from the Science and Technology Facilities Council which is part of UKRI, Horizon 2020 and the National Science Foundation, USA.


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