The Compact Muon Solenoid (CMS) is a general-purpose detector at the Large Hadron Collider (LHC). It has a broad physics programme ranging from studying the Standard Model (including the Higgs boson) to searching for extra dimensions and particles that could make up dark matter. The CMS detector is built around a huge solenoid magnet. This takes the form of a cylindrical coil of superconducting cable that generates a field of 4 tesla, about 100,000 times the magnetic field of the Earth. The field is confined by a steel yoke that forms the bulk of the detectors 14,000-tonne weight. Credit: CERN

The ATLAS and CMS collaborations at the Large Hadron Collider have seen evidence of a new type of decay not yet observed: the Higgs boson decaying into a pair of muons.

US CMS the United States contingent of the global CMS collaboration played a crucial role in this result, contributing to the excellent performance of CMS detector. US CMS members have been instrumental in the design, construction and upgrades of detector components that capture the particle tracks and help filter potential signals from the background noise: the tracker detector, the muon detectors, the muon trigger system and the computing system. They continue to lead the successful maintenance and operations of these systems.

US CMS is very proud to acknowledge the significant impact made by its members in deploying innovative analysis techniques, including cutting-edge AI methods, which were critical in establishing the evidence for Higgs boson decays into a muon and antimuon pair, said Brown University physicist Meenakshi Narain, chair of the US CMS collaboration. This is a rare process, and finding evidence for it is a vital step toward understanding the Higgs particle and the Standard Model.

CMS is an international collaboration with members from 238 institutes across 55 countries. US CMS, hosted by the U.S. Department of Energys Fermi National Accelerator Laboratory, makes up about a third of the CMS collaboration.

The achievement, reached significantly ahead of what was expected, relies on the excellent performance of our detector, on the large data set provided by LHC and on advanced analysis techniques, said Roberto Carlin, spokesperson for the CMS experimental collaboration.

The ATLAS and CMS experiments at CERN have announced new results that show that the Higgs boson decays into two muons. The muon is a heavier copy of the electron, one of the elementary particles that constitute the matter content of the universe. While electrons are classified as a first-generation particle, muons belong to the second generation. The physics process of the Higgs boson decaying into muons is a rare phenomenon as only about one Higgs boson in 5,000 decays into muons. These new results have pivotal importance for fundamental physics because they indicate for the first time that the Higgs boson interacts with second-generation elementary particles.

Physicists at CERN have been studying the Higgs boson since its discovery in 2012 to probe the properties of this very special particle. The Higgs boson, produced from proton collisions at the Large Hadron Collider, disintegrates referred to as decay almost instantaneously into other particles. One of the main methods of studying the Higgs bosons properties is by analyzing how it decays into the various fundamental particles and the rate of disintegration.

A candidate of a Higgs boson decays into two muons as recorded by CMS. Credit: CMS collaboration, CMS collaboration, Thomas McCauley

CMS achieved evidence of this decay with 3 sigma, which means that the chance of seeing the Higgs boson decaying into a muon pair from statistical fluctuation is less than one in 700. ATLAS two sigma result means the chances are one in 40. The combination of both results would increase the significance well above 3 sigma and provides strong evidence for the Higgs boson decay to two muons.

CMS is proud to have achieved this sensitivity to the decay of Higgs bosons to muons and to show first experimental evidence for this process. The Higgs boson seems to interact also with second-generation particles in agreement with the prediction of the Standard Model, a result that will be further refined with the data we expect to collect in the next run, says Roberto Carlin, spokesperson for the CMS experiment.

The Higgs boson is the quantum manifestation of the Higgs field, which gives mass to elementary particles it interacts with, via the Brout-Englert-Higgs mechanism. By measuring the rate at which the Higgs boson decays into different particles, physicists can infer the strength of their interaction with the Higgs field: the higher the rate of decay into a given particle, the stronger its interaction with the field. So far, the ATLAS and CMS experiments have observed the Higgs boson decays into different types of bosons such as W and Z, and heavier fermions such as tau leptons. The interaction with the heaviest quarks, the top and bottom, was measured in 2018. Muons are much lighter in comparison, and their interaction with the Higgs field is weaker. Interactions between the Higgs boson and muons had, therefore, not been seen at the LHC.

A candidate ATLAS event display of a Higgs boson decay to two muons. Credit: ATLAS collaboration

This evidence of Higgs boson decays to second-generation matter particles complements a highly successful Run 2 Higgs physics program. The measurements of the Higgs bosons properties have reached a new stage in precision and rare decay modes can be addressed. These achievements rely on the large LHC data set, the outstanding efficiency, and performance of the ATLAS detector, as well as the use of novel analysis techniques, says Karl Jakobs, ATLAS spokesperson.

What makes these studies even more challenging is that, at the LHC, for every predicted Higgs boson decaying to two muons, there are thousands of muon pairs produced through other processes that mimic the expected experimental signature. The characteristic signature of the Higgs bosons decay to muons is a small excess of events that cluster near a muon-pair mass of 125 GeV, which is the mass of the Higgs boson. Isolating the Higgs boson to muon-pair interactions is no easy feat. To do so, both experiments measure the energy, momentum and angles of muon candidates from the Higgs bosons decay. In addition, the sensitivity of the analyses was improved through methods such as sophisticated background modeling strategies and other advanced techniques such as machine-learning algorithms. CMS combined four separate analyses, each optimized to categorize physics events with possible signals of a specific Higgs boson production mode. ATLAS divided their events into 20 categories that targeted specific Higgs boson production modes.

The results, which are so far consistent with the Standard Model predictions, used the full data set collected from the second run of the LHC. With more data to be recorded from the particle accelerators next run and with the High-Luminosity LHC, the ATLAS and CMS collaborations expect to reach the sensitivity (5 sigma) needed to establish the discovery of the Higgs boson decay to two muons and constrain possible theories of physics beyond the Standard Model which would affect this decay mode of the Higgs boson.

References:

Measurement of Higgs boson decay to a pair of muons in proton-proton collisions at s=13TeV by CMS Collaboration, 29 July 2020, CMS Physics Analysis Summaries.Report: CMS-PAS-HIG-19-006

A search for the dimuon decay of the Standard Model Higgs boson with the ATLAS detector by ATLAS Collaboration, 15 July 2020, High Energy Physics Experiment.arXiv: 2007.07830

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Large Hadron Collider Detects Evidence of a Rare Higgs Boson Process: God Particle Decaying Into a Pair of Muons - SciTechDaily