Tag Archives: boson

Physicists at CERN witness the creation of weak boson triplet

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The physicist with Atlas collaboration We presented our first observations of VVZ production at Cern's large Hadron Collider. This is a rare combination of three giant vector bosons.

Three vector boson events recorded by Atlas are when one W-boson collapses into electrons and neutrinos, one collapses into moons and neutrinos, and two moons collapses into z boson. Muons are shown with a red line, electrons are shown with a green line, and a white line where “loss of energy” from Neutrino is destroyed. Image credits: Atlas/Cern.

As carriers of weak forces, W and Z bosons are central to standard models of particle physics.

Accurate measurements of multiboson production processes provide excellent testing of standard models and shed light on new physical phenomena.

“The production of three vector (V) bosons is a very rare process in LHC,” says Dr. Fabio Cerutti, Ph.D., Atlas Physics Coordinator.

“The measurement provides information about the interactions between multiple bosons linked to the symmetry underlying the standard model.”

“It is a powerful tool to uncover new physics phenomena, such as new particles that are too heavy to be produced directly in LHC.”

The Atlas team observed the generation of VVZ with statistical significance of 6.4 standard deviations, exceeding the five standard deviation thresholds needed to assert the observations.

This observation extends previous results from Atlas and CMS collaborations, including observations of VVV production by CMS and observations of WWW production by Atlas.

As some of the heaviest known particles, W and Z bosons can collapse in countless different ways.

In a new study, Atlas physicists focused on seven attenuation channels with the highest discovery potential.

These channels were further refined using a machine learning technique called Boosted Decision Trees, where the algorithms for each channel were trained to identify the desired signal.

By combining the attenuation channels, researchers were able to observe the production of VVZ and set limits on the contributions of new physical phenomena to the signal.

“The resulting limitations confirm the validity of the standard model and are consistent with previous results on the generation of three vector bosons,” they said.

“Analyzing the third run of LHC and the large dataset from future HLHCs will further improve the measurements of the generation of three vector bosons. We will deepen our understanding of these basic particles and our role in the universe.”

Team's result It will be published in journal Physical character b.

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Atlas collaboration. 2025. Observation of VVZ production at S√=13 TEV using an ATLAS detector. Phys. Rhett. bin press; Arxiv: 2412.15123

Source: www.sci.news

Exploring the Production of Higgs Boson Pairs in Proton-Proton Collisions with the CMS Experiment

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CMS Collaboration physicists used data from high-energy proton-proton collisions from Experiment 2 at CERN’s Large Hadron Collider (LHC) to released The latest research into the production of Higgs boson pairs, known as De-Higgs, has placed constraints on the rate of their formation.

Event display of candidate events for Higgs pair generation. Image credit: CERN.

According to physicists, Higgs particle pair can be created in two main ways.

The first is called gluon-gluon fusion, in which gluons (particles inside colliding protons) interact to produce the Higgs boson. This process allows scientists to study the interaction between one so-called intermediate state Higgs boson and two final state Higgs bosons.

The second method involves quarks, also inside the colliding protons, which emit two vector bosons. These vector particles interact to form a Higgs particle, allowing the study of the interaction between two Higgs particles and two vector particles.

CMS physicists performed the latest analysis by exploring multiple ways DeHiggs could collapse.

These final states resulted from the decay of Higgs boson pairs into bottom quarks, W particles, tau leptons, and photons.

By combining these searches and analyzing all the data simultaneously using advanced analytics techniques such as boosted decision trees and deep neural networks, the collaboration was able to extract more information than ever before. .

This study allowed the researchers to set an upper bound on the Higgs pair production rate with a 95% confidence level.

The measured limits are now 3.5 times higher than the Standard Model’s prediction for total DeHiggs production and 79 times higher than the Standard Model’s prediction for DeHiggs production by vector boson fusion.

The LHC’s Run 3 data acquisition era is underway, and the amount of data collected by CMS experiments has already doubled, and CMS researchers are making progress in analyzing it.

One of the most exciting prospects for measuring the self-interactions of the Higgs boson is the upcoming High-Luminosity LHC (HL-LHC), scheduled to become operational in 2030.

In this new phase, the accelerator will provide CMS with the highest luminosity ever reached in a collider.

Considering luminosity predictions and systematic uncertainties, scientists estimate that the first evidence of Higgs formation may begin to appear in about half of the HL-LHC data.

“We look forward to further investigating this rare and exciting phenomenon,” they said.

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CMS cooperation. 2024. Combined search for non-resonant Higgs boson pair production in proton-proton collisions at √s=13 TeV. CMS-PAS-HIG-20-011

Source: www.sci.news