Tag Archives: Quark

Physicists at CERN investigate potential Lorentz symmetry violations in top quark pair production

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A physicist in charge of CERN’s large -scale Hadronco Rider has tested whether top queks follow Albert Einstein’s special theory.

Installation of CMS beam pipe. Image credit: CERN / CMS collaboration.

In addition to quantum mechanics, Albert Einstein’s special relativity is functioning as the basis of the standard model of particle physics.

In that mind, there is a concept called Lorentz symmetry. The experimental results do not depend on the direction or speed of the experiment in which they were taken.

Special relativity has endured the trials of time. However, some theories, including specific models in string rationale, predict that very high energy does not work with special relativity and experimental observation depends on the direction of space -time experiments.

Lorentz’s remnants of the symmetry destruction can be observed with low -energy, such as the energy of a large hoodron co -rider (LHC), but has not been found on LHC or other colliders despite previous efforts.

In a new study, CMS physicists have searched for Lorentz symmetry on LHC using the top quark pair, the most known basic particles.

“In this case, relying on the direction of the experiment means that the speed at which the top quark pair is generated by the LHC collision in the LHC is different over time,” they said.

“To be more accurate, the average direction of the top quark generated in the center of the LHC proton beam and the center of the CMS experiment also changes because the earth rotates around the axis.”

“As a result, and if there is a priority in space -time, the production rate of the highest pair varies by era.”

“Therefore, finding a deviation from a certain speed will discover the direction of space -time priority.”

The new results of the team based on the LHC’s second execution data consistent with a certain speed. In other words, Lorentz’s symmetry is not broken, and Einstein’s special relativity remains effective.

Researchers have used results to limit the size of the parameters that are predicted to be null when symmetry is maintained.

The obtained restrictions have improved up to 100 times with the previous search results, which were destroyed by Lorentz symmetry in the previous Tevatron accelerator.

“The results will open a way to search for the future in which Lorentz symmetry will be destroyed based on the top quark data from the third run of LHC,” said scientists.

“Open the door to scrutinization of processes including other heavy particles that can only be investigated on LHC, such as Higgs Boson, W and Z Bosons.”

study Published in the October 2024 issue of the journal Physics B.

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CMS collaboration. 2024. Use the Dilepton Event in the 13 TEV Proton Proton collision to search for Lorentz invaluity in the production of top quark pairs. Physics B 857: 138979; DOI: 10.1016/j.physletb.2024.138979

Source: www.sci.news

Physicists at CERN witness a top quark pair in lead-lead collision

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The generation of top quark pairs is observed This process of interaction between atomic nuclei was observed for the first time in lead-lead collisions at CERN's Large Hadron Collider (LHC) and the ATLAS detector.

We show lead-lead collisions at 5.02 TeV per nucleon pair, resulting in the production of candidate pairs of top quarks that decay into other particles. This event contains four particle jets (yellow cone), one electron (green line), and one muon (red line). The inlay shows an axial view of the event. Image credit: ATLAS/CERN.

In quark-gluon plasma, quarks (matter particles) and gluons (strong force transmitters), which are the basic constituents of protons and neutrons, are not bound within particles and exist in an unconfined state of matter, and almost It forms a complete dense fluid.

Physicists believe that quark-gluon plasma filled the universe shortly after the Big Bang, and their study provides a glimpse into conditions at earlier times in the universe's history.

However, the lifespan of quark-gluon plasma produced by heavy ion collisions is extremely short, approximately 10 years.-twenty three Seconds — means not directly observable.

Instead, physicists study the particles produced in these collisions that pass through the quark-gluon plasma and use them as probes of the plasma's properties.

In particular, the top quark is a very promising probe of the evolution of quark-gluon plasmas over time.

The top quark, the heaviest elementary particle known, decays into other particles an order of magnitude faster than the time required to form a quark-gluon plasma.

The delay between the collision and the decay products of the top quark interacting with the quark-gluon plasma may serve as a “time marker” and provide a unique opportunity to study the temporal dynamics of the plasma.

In addition, physicists could potentially extract new information about the nuclear parton distribution function, which describes how the momentum of a nucleon (proton or neutron) is distributed among its constituent quarks and gluons.

In the new study, physicists from the ATLAS collaboration studied lead ion collisions that occurred during LHC Experiment 2 at a collision energy of 5.02 teraelectronvolts (TeV) per nucleon pair.

They observed the production of a top quark in a dilepton channel, where the top quark decays into a bottom quark and a W boson, which then decays into an electron or muon and its associated neutrino.

This result has statistical significance with a standard deviation of 5.0, and is the first observation of the production of a top quark pair in a nucleus-nucleus collision.

“We measured the production rate, or cross section, of the top quark pair with a relative uncertainty of 35%,” the physicists said.

“The overall uncertainty is primarily driven by the size of the dataset, which means new heavy ion data from the ongoing Experiment 3 will improve the accuracy of the measurements.”

“The new results open the door to the study of quark-gluon plasmas,” the researchers added.

“Future studies will also consider semi-leptonic decay channels for top quark pairs in heavy ion collisions. This may provide the first glimpse of the evolution of quark-gluon plasmas over time.” ”

Source: www.sci.news

Huge Neutron Stars Could Have Cores Composed of Unconfined Quark Matter

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The core of a neutron star contains the highest density of matter in the universe. This highly compressed matter can undergo a phase transition in which nuclear matter dissolves into unconfined quark matter, releasing its constituent quarks and gluons. However, it is currently unknown whether this transition occurs inside at least some physical neutron stars. In a new study, physicists from the University of Helsinki, the University of Stavanger, the Flatiron Institute, and Columbia University quantified this possibility by combining information from astrophysical observations and theoretical calculations.

Artist's impression of a neutron star. Image credit: Sci.News.

Neutron stars are extreme astrophysical objects containing the densest matter found in the modern universe.

It has a radius of about 10 km (6 miles) and a mass of about 1.4 solar masses.

“A long-standing unresolved question concerns whether the enormous central pressure of a neutron star can compress protons and neutrons into a phase called cold quark matter. In this exotic state, individual protons and neutrons no longer exist. We don’t,” said Professor Aleksi Vuorinen of the University of Helsinki.

“The quarks and gluons that make them up are instead freed from typical color confinement and can move almost freely.”

In a new paper, Professor Vuorinen and colleagues provide the first quantitative estimate of the possibility of a core of quark matter existing inside a massive neutron star.

They showed that quark matter is almost inevitable in the most massive neutron stars, based on current astrophysical observations. The quantitative estimates they extracted put the likelihood in the 80-90% range.

For there to be a small chance that all neutron stars are composed only of nuclear matter, the change from nuclear matter to quark matter must occur through a strong primary phase similar to the phenomenon in which liquid water turns to ice. Must be a metastasis.

This type of rapid change in the properties of neutron star matter could destabilize the star in such a way that even the formation of a tiny quark matter core could cause the star to collapse into a black hole.

An artist's impression of the various layers inside a giant neutron star. The red circle represents a significant amount of quark matter core. Image credit: Jyrki Hokkanen, CSC.

“A key element in deriving the new results is a series of large-scale supercomputer calculations that utilize Bayesian inference, a branch of statistical deduction that estimates the likelihood of various model parameters through direct comparison with observed data. “, the authors explained.

“We demonstrate that the Bayesian component allows us to derive new limits on the properties of neutron star matter, approaching the so-called conformal behavior near the center of the most massive and stable neutron stars.”

Dr. Joonas Nettila from the University of Helsinki added: “It is interesting to see specifically how each new neutron star observation improves the ability to estimate the properties of the neutron star material.” .

“Being able to compare theoretical predictions with observations and constrain the possibility of quark-matter nuclei requires hundreds of supercomputers,” said Jonas Hirvonen, a doctoral student at the Flatiron Institute and Columbia University. “We had to spend tens of thousands of CPU hours.”

“We are very grateful to the Finnish Supercomputer Center CSC for providing us with all the necessary resources.”

of paper It was published in the magazine nature communications.

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E.Annara other. 2023. Strongly interacting matter exhibits unconfined behavior in massive neutron stars. Nat Commune 14, 8451; doi: 10.1038/s41467-023-44051-y

Source: www.sci.news