A recent study conducted by physicists at the University of Oxford, Johns Hopkins, and the Institute of Astrophysics in Paris reveals a natural process involving a gravitational particle charger that utilizes free-falling particles from infinity, matter collisions from the most stable circular orbit of rotating black holes, and a gravitational particle charger that repeatedly cycles mass energy—excluding heavy particles. In essence, this describes the Super Collider.
The artist’s concept depicts an ultra-high massive black hole in the heart of the Milky Way galaxy known as Sagittarius A*. Image credits: NASA/ESA/CSA/RALF CRAWFORD, STSCI.
Particle corridors accelerate protons and other subatomic particles towards one another at nearly the speed of light, revealing the fundamental properties of matter.
A subtle energy flash occurs upon collision, with fragments potentially unveiling previously unknown particles that may serve as candidates for dark matter—a crucial, yet elusive, component of the universe that remains undetected by scientists.
Facilities like the Large Hadron Collider also contribute to advancements in areas such as the internet, cancer therapy, and high-performance computing.
“One of the great aspirations for a particle collider like the Large Hadron Collider is to produce dark matter particles, though we have yet to find any evidence,” commented Professor Joseph Silk, an astrophysicist from Johns Hopkins University and Oxford University.
“This is why there’s ongoing dialogue about the necessity of constructing a much more powerful version for the next generation of Super Collider.”
“However, we’ve been waiting for 40 years to invest $30 billion in building this Super Collider, allowing nature to give us a glimpse into the future with supermassive black holes.”
A black hole can rotate around its axis like a planet but possesses significantly greater strength due to its intense gravitational field.
Increasingly, scientists are discovering that massive black holes rapidly spinning at the center of galaxies release enormous explosions of plasma, potentially due to jets transporting energy from the spin and surrounding accretion disks.
These phenomena can yield similar results to those produced by engineered Super Colliders.
“If ultra-high energy black holes can generate these particles through high-energy proton collisions, we could receive signals on Earth. Some high-energy particles pass through the detectors rapidly,” Professor Silk explained.
“This indicates a new particle collider effect within one of the universe’s most mysterious entities, achieving energies unattainable by any accelerator on Earth.”
“We may observe something with a unique signature believed to indicate the presence of dark matter. While this is somewhat speculative, it remains a possibility.”
New research indicates that gas falling into a black hole can harness energy from its spin, resulting in more violent behavior than previously thought.
Near rapidly spinning black holes, these particles can collide in a coordinated manner.
While not identical, this process resembles the collisions created using strong magnetic fields, where particles are accelerated in a circular high-energy particle corridor.
“Some particles from these collisions are swallowed by the black hole and vanish forever,” stated Professor Silk.
“However, due to their energy and momentum, some particles emerge, achieving unprecedented high energies.”
“We have recognized the immense energy of these particle beams, rivaling what can be produced in a Super Collider.”
“Determining the limits of this energy is challenging, but these phenomena are certainly aligned with the energy levels of the latest Super Colliders we plan to construct, providing complementary results.”
To detect such high-energy particles, scientists can utilize observatories that are already monitoring supernovae, massive black hole eruptions, and other cosmic occurrences.
These include detectors like the IceCube Neutrino Observatory and the Kilometer Cube Neutrino Telescope in Antarctica.
The difference between a Super Collider and a black hole is their vast distances from one another. Nevertheless, these particles still reach us.
The team’s paper was published this week in the journal Physical Review Letters.
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Andrew Mamalie and Joseph Silk. 2025. Black Hole Super Collider. Phys. Rev. Lett. 134, 221401; doi:10.1103/physrevlett.134.221401
Source: www.sci.news
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