Astronomers have identified the largest known cloud of energy particles encircling galaxy clusters, with around 20 million annual clouds around the galaxy cluster PLCK G287.0+32.9.
This new composite image, created using X-rays from NASA’s Chandra X-Ray Observatory (blue and purple), radio data from Meerkat Radio Telescope (orange and yellow), and optical images from Panstarrs (red, green, and blue), illustrates the giant galaxy cluster PLCK G287.0+32.9. Image credit: NASA/CXC/CFA/Rajpurohit et al. / panstarrs / sarao / meerkat / sao / n. wolk.
Located 5 billion light years from Earth in the Hydra constellation, PLCK G287.0+32.9 has garnered astronomers’ attention since its initial detection in 2011.
Prior research uncovered two bright relics, revealing a massive shock wave illuminating the cluster’s edges. However, the extensive, faint radio emissions filling the space between them went unnoticed.
Recent radio images have shown that the entire cluster is enveloped in a faint radio glow that is nearly 20 times the diameter of the Milky Way, suggesting an extraordinary and powerful phenomenon at play.
“We anticipated finding a bright pair of relics at the cluster’s edge. Found “The Harvard & Smithsonian Astrophysics Center” mentioned: “The Harvard & Smithsonian’s Astrophysics Center is a great way to help you get started,” Dr. Kamursh Rajprohit, an astronomer at the Harvard & Smithsonian Center for Astrophysics, noted.
“No energy particle clouds of this magnitude have been spotted in such galaxy clusters or anything comparable.”
Previous record holders, located around Abel 2255 in the Galaxy Cluster, spanned about 16.3 million light years.
In the central region of the cluster, Dr. Rajprohit and his team identified radio halos where frequencies of this scale are typically undetectable, marking the first discovery of size at 114 million light years at 2.4 GHz.
The findings posed questions for the team, providing compelling evidence of magnetic fields where cosmic ray electrons and magnetic fields extend throughout the cluster.
However, it remains uncertain how these electrons can accelerate over such vast distances.
“Very extended radio halos are seldom visible across most frequencies, as the electrons responsible for them tend to lose energy. They are aged and have cooled over time,” Dr. Rajpurohit stated.
“The discovery of this colossal halo has now led to a significant increase in radio emissions between the catastrophic impact and the rest of the cluster.”
“This suggests something is actively accelerating or re-accelerating the electrons, yet none of the usual explanations apply.”
“We suspect that extensive shock waves and turbulence may be contributing factors, but additional theoretical models are needed to arrive at a definitive conclusion.”
This discovery offers researchers a new pathway to investigate cosmic magnetic fields—one of the primary unanswered questions in astrophysics—helping to elucidate how magnetic fields shape the universe on the largest scales.
“We’re beginning to perceive space in ways we have never imagined,” Dr. Rajprohit emphasized.
“This necessitates a reevaluation of how energy and matter traverse through its grandest structures.”
“Observations from NASA’s Chandra X-ray Observatory, managed by the Smithsonian Astrophysical Observatory, reveal boxy structures, comet-like tails, and several other distinct features of the cluster’s hot gas, indicating that the cluster is highly disturbed.”
“Some of these X-ray features correspond with radio-detected structures, pointing to substantial shocks and turbulence driven by merging events, facilitating electron acceleration or re-acceleration.”
“In the core of a cluster, some of these features may arise from the merger of two smaller galaxy clusters, or an explosion triggered by an exceptionally large black hole, or a combination of both.”
Source: www.sci.news