Since federal funding decreases decades of research, scientists can turn black holes for natural alternatives to expensive black facilities, as well as such ridiculous particles that have deep secrets in the universe.
These results can help build billions of dollars and decades of costs needed for Europe’s largest Hudron Colider, such as the Research Complex, which is the world’s largest and highest energy particle.
“One of the great hopes for particle collisters like big headron collectors,” said John Hopkins University and University of Oxford, co -author of astronomer Study, a UK expert, said Joseph Silk, a co -authored by Professor Study, a UK specialist, said, “There is a great hope for particle collisters such as the collector that will produce any evidence of dark matter, but we have not seen any evidence yet.” “That’s why a very powerful version continues to negotiate to build the next generation of Super Colder. But when we invest $ 30 billion and wait 40 years to build this super colider-the nature can provide a glimpse of the future in the black holes on a large scale.”
This research was published on June 3 Physical review posts.
Particular colliders break the proton and other subtomatic particles in each other at the speed of light, which expose the most basic aspects of the material. The collision may reveal the precise energy sparkle and the particles discovered before the debris, including the potential candidate for the dark matter, an important but an important part of the universe that scientists have not yet known. Facilities like Large Headron Colider, a 17 -mile circular tunnel, have also helped to change the Internet, cancer therapy, and high -performance computing.
A black hole can revolve around its axis like a planet, but with a lot of strength due to its severe gravity field. Scientists have quickly discovered that rapidly wandering in galaxies centers are highly stimulated by plasma, which is because jets drive energy from their spin and surrounding acne disc. These are the events that can potentially produce the same results, such as human -made supercomppeers, new studies.
“If Super Massie Black Hole can manufacture these particles through high -energy proton collision, we can find a gesture on the ground, some really high energy particles pass through our detector,” said Silk, who is also a researcher at the Institute of Astro Physics in Paris and the University of Oxford. “It will be a proof of a novel particle cooler within the most mysterious objects of the universe, which is to achieve energies that will be unacceptable in any adventurous accelerator. We will see something with a strange signature that clearly provides evidence for the dark matter, which is possible but a little leap.”
New research suggests that jumping “gas flow” near the black hole can cause energy from its spin, which is more violent than scientists. Near the rapidly rotating black hole, these particles can hit chaos. Although not the same, this process is like collisions that scientists have created using severe magnetic fields to accelerate particles in the circular tunnel of a high -energy particle colider.
Silk said, “Some particles from these collisions go down the throat of the black hole and disappear forever. But because of their energy and speed, anything comes out, and these are the same people who are brought to unprecedented high energies.” “We found out how dynamic these particles beams can be: the more powerful you get from the Super Colder, or more. It is very difficult to say what the limit is, but they are definitely dependent on the energy of the latest supercompuliar that we intend to make, so they can certainly give us the results.”
Silk said that to detect such high energy particles, scientists can already use sprinka, large -scale black hole burst and other cosmic events. These include detectors such as the Ice Cube Neutrono Observatory or kilometer cube neutronic telescope in the south, which recently detected the most passionate neutrino recorded under the Mediterranean.
Silk said, “The difference between a super cold and black hole is that the black holes are far away.” “But yet, these particles will be found to us.”
Dr. Andrew Mamri, a theoretical physicist at Oxford University, is also the author of the study.
