The Higgs boson can be a unique portal to finding signs of dark matter due to its own distinctive characteristics and properties.Fundamental particles in our universe acquire mass through their interactions with the Higgs field.One theoretical model of new physics predicts five Higgs bosons. There may be more than one Higgs boson.The Higgs boson gets its mass just like other particles-from its own interactions with the Higgs field.These experiments are making precise measurements of the Higgs boson’s properties to determine if it matches the Standard Model predictions or offers clues to new physics, exploring new particles and their interactions, and identifying the new physics of dark matter. They also play leadership roles in many aspects of each experiment. researchers account for approximately 20% and 25% of the ATLAS and CMS collaborations, respectively. The LHC hosts four large experimental particle detectors, two of which are partially supported by SC’s Office of High Energy Physics: ATLAS and CMS. DOE also supports many scientists, engineers, and technicians in the LHC program. The DOE Office of Science (SC) contributed important accelerator magnets to help construct the LHC. It is currently the only place scientists can create and study Higgs bosons. The LHC at CERN is the highest-energy particle collider in the world. DOE Office of Science: Contributions to Higgs Boson Research If the Higgs boson deviates from the model, it may provide clues to new particles that only interact with other Standard Model particles through the Higgs boson and thereby lead to new scientific discoveries. Scientists are now studying the characteristic properties of the Higgs boson to determine if it precisely matches the predictions of the Standard Model of particle physics. This discovery led to the 2013 Nobel Prize in Physics being awarded to Higgs and Englert. Scientists confirmed its existence in 2012 through the ATLAS and CMS experiments at the Large Hadron Collider (LHC) at CERN in Switzerland. The Higgs boson was proposed in 1964 by Peter Higgs, François Englert, and four other theorists to explain why certain particles have mass. The photon, which is the particle of light and carries the electromagnetic force, has no mass at all. A particle’s mass determines how much it resists changing its speed or position when it encounters a force. The Higgs boson is the fundamental particle associated with the Higgs field, a field that gives mass to other fundamental particles such as electrons and quarks.
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