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Here’s what you will learn when you read this story:
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Although Chern’s major adronymous collision had a lasting impact on particle physics, he has not yet opened a whole new border to particle physics, as some scientists expected.
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A scientist champions in theory that the new physics can be hidden in what he calls “Zeptouverse” – the sphere of objects on the scale of the zopometer (which is 1 quintillion per meter) – and the best way to explore this universe by observing Kaon and B Monzon.
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Future clashes will probably be able to directly monitor Zeptouverse, but so far studying these breakups can help us find new physics within the decade.
We humans have done quite well in looking at the invisible. The great adronymia-collision-our prime minister’s instrument for the study of subatomic-can thoroughly explore the world of the atometer, which is (incredible) only a single-cycle of a meter. It is known that LHC confirmed the existence of Boson Higgs in 2012 and physicists were preparing for the rush of new particles to explain the prolonged mysteries of the universe, such as the existence of dark matter and atymmetry of matter.
But this explosion of discovery does not really materialize. This is certainly not to say nothing It has happened since then, but no major revelations have been found in the Higgs norms since then. And now, a new article in ScientistWritten by Harry Cliff Particle Physics, who works in the LHCB experiment, describes in detail a theory of Why We didn’t find what we expected to find. Most basic, many of these revelations could hide in what is sometimes called “Zeptouverse”, which is a world that exists only at 10-21-Mome scale. LHC can only analyze the particles directly up to 50 rears, but Cliff emphasizes theory – the most commonly supported by the Technical University of Munich Theoretical Physicist Andrzej Buras – that these elusive particles can simply be beyond the opportunities to open LHC.
Of course, a better detector can open this border -CERN has completed a study on the feasibility of the future circular collision (FCC) just earlier this year. But Buras believes we can explore this limit of new physics indirectly Without having to wait a few decades needed for the final study of this issue (FCC will not perform high -energy physics by 2070). In 2020, Buras examined this issue in an article about PhysicianWriting:
Can we get to Zeptouveniverse, ie. resolution up to 10–21M or energies up to 200 tev, through Quark’s scent physics and Lepton’s aroma, which violates the processes during this decade, long before possible through a collector built in this century?
In a document uploaded to the front server ARXIV Last year, Buras identified seven possible goals for this investigation, which he called the “magnificent seven”, according to ScientistS All seven are extremely rare particle decay containing strange and lower quarters, which Cliff calls “echo from Zeptouverse.” Fortunately for Buras, some experiments are already looking for these ultra-rare decay.
One example of such a breakup begins with B Meson – a type of composite particle made of different quarks, as Cliff explains. In 2023, The Belle II experiment in Japan It captures this breakup into action, producing another particle called Kaon (or K Meson) and two neutrinos. However, since the experiment is not set up for direct discovery of neutrino, their information is limited.
This is not the only ultra-rire breakdown that has also been discovered recently. In September 2024, the Na62 experiment in Cern recorded the breakup of a positively charged Kaon in Pion and a couple of the matter of matter. It is believed that less than one in 10 billion Kaoni should break up in this way. As this interaction is sensitive to the standard deviations of the model, it is identified as one of the main goals for finding new physics. Today, the Koto experiment in Japan is looking for a second confirmation of this breakup of Kaon.
“The search for new particles and forces beyond the standard model is highly motivated by the need to explain the dark matter, the huge range of particles of particles from a little neutrino to the massive upper quark and the asymmetry between matter and antimatter that are responsible for our existence,” Buras writes last year Cern courierS “As the direct search in LHC has not yet provided any idea of what these new particles and forces may be, the indirect searches are growing in importance.”
Scientists are just beginning to peek inside the unknown border of Zeptouverse and until they are executed and run, these extremely rare breakups are ours only Windows in this universe.
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