A new study, published in The Astrophysical Journal, has produced a compressed 14-year movie of the sun observed in gamma rays, a visualization tool which revealed that—contrary to the expected uniform distribution of these high energy photons—the solar disk can become brighter on the polar regions. This tendency for the sun’s glow in the gamma rays to be dominant at the highest latitudes is evident during the peak of solar activity, as could be seen in June of 2014.
The study, led by Bruno Arsioli, of the Institute of Astrophysics and Space Sciences (IA), in Portugal, and the Faculty of Sciences of the University of Lisbon, may contribute to the understanding of the yet unknown process that makes the sun shine 10 times brighter in gamma rays than physicists expect. It may also inform space weather forecasts.
Solar gamma rays are produced in our star’s halo and in solar flares, but are also released from its surface. “The sun is stormed with close to light-speed particles coming from beyond our galaxy in all directions,” says Bruno Arsioli. “These so-called cosmic rays are electrically charged and are deflected by the sun’s magnetic fields. Those that interact with the solar atmosphere produce a shower of gamma rays.”
Scientists thought these showers had equal chances of being seen anywhere across the sun’s disk. What this work suggests is that cosmic rays might interact with the sun’s magnetic field and thus produce a gamma-ray distribution that is not uniform across all latitudes of our star.
“We also detected a difference in energy between the poles,” Bruno Arsioli adds. “In the south pole there is a surplus of emissions of higher energy, of photons with 20 to 150 GeV, while most of the less energetic photons come from the north pole.” Scientists haven’t yet an explanation for this asymmetry.
During the maximum of the solar activity cycle, it is evident that gamma rays are being radiated more often at higher latitudes. They were particularly concentrated on the solar poles in June of 2014, upon the reversal of the solar magnetic field. This is when the sun’s magnetic field dipole swaps its two signs, a peculiar phenomenon that is known to happen at the peak of solar activity, once every 11 years.
“We have found results that challenge our current understanding of the sun and its environment,” says Elena Orlando, of University of Trieste, INFN, and Stanford University, and co-author of this study.
“We demonstrated a strong correlation of the asymmetry in the solar gamma-ray emission in coincidence with the solar magnetic field flip, which has revealed a possible link among solar astronomy, particle physics, and plasma physics.”
The data used came from 14 years of observations with the gamma rays satellite Fermi Large Area Telescope (Fermi-LAT), between August 2008 and January 2022. This period covered a full solar cycle, from a minimum to the next, with the peak in 2014.
One of the challenges was to disentangle solar emissions from the numerous other sources of gamma rays in the background sky, crossed by the apparent trajectory of the sun. Bruno Arsioli and his colleague Elena Orlando produced a tool to integrate all the solar gamma-ray events within a window of the order of 400 to 700 days, and this window can slide across the 14-year period.
Through this visualization, the moments of polar excesses became clear, as well as the energy discrepancy between north and south.
“The study of gamma-ray emissions from the sun represents a new window to investigate and understand the physical processes that happen in the atmosphere of our star,” says Arsioli. “What are the processes that create these excesses at the poles? Maybe there are additional mechanisms generating gamma rays that go beyond the interaction of cosmic rays with the surface of the sun.”
Yet, if we stick to cosmic rays, they may work as a probe of the inner solar atmosphere. The analysis of these Fermi-LAT observations also motivates a new theoretical approach that should consider a more detailed description of the magnetic fields of the sun.
The possible connection between the sun’s production of gamma rays and its spectacular periods of more frequent solar flares and coronal mass ejections, and between these and the changes in the magnetic configuration of our star, may help to improve the physical models that predict solar activity. These are the basis of space weather forecasts, essential to protect instruments on satellites in space and telecommunications and other electronic infrastructures on Earth.
“In 2024 and the next year we will experience a new solar maximum, and another inversion of the sun’s magnetic poles has already started. We expect by the end of 2025 to reassess if the inversion of the magnetic fields is followed by a surplus in the gamma rays emissions from the poles,” says Bruno Arsioli.
Elena Orlando adds, “We have found the key to unlock this mystery, which suggests the future directions that should be taken. It is fundamental that the Fermi telescope will operate and observe the sun in the coming years.”
But the solar gamma rays are likely to have more to reveal and demand further attention. This study will strengthen the scientific case for the continuous monitoring of the sun by the next generation of gamma rays space observatories.
“If it is settled that high energy emissions really carry information about the solar activity, then the next mission should be planned to provide real time data on gamma-ray emissions from the sun,” says Arsioli.
More information:
Yet Another Sunshine Mystery: Unexpected Asymmetry in GeV Emission from the Solar Disk, The Astrophysical Journal (2024). DOI: 10.3847/1538-4357/ad1bd2
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University of Lisbon
Citation:
Will this new solar maximum solve the puzzle of the sun’s gamma-ray picture? (2024, February 7)