New Experiments Reveal How Strongly Higgs Boson Interacts With Top Quark, Heaviest Known Elementary Particle

New results from the ATLAS and CMS ( Compact Muon Solenoid) experiments at the Large Hadron Collider (LHC) reveal how strongly the Higgs boson interacts with the top quark – the heaviest known elementary particle  – corroborating our understanding of the Higgs and setting constraints on new physics.

Cern. Foto: Courtesy Everett Collection/IBL

These new results were possible to obtain when scientists on the CMS experiment at the Large Hadron Collider made attempts to  determine how the Higgs boson fits into the delicate ecosystem of particles.

“We know that the Higgs interacts with massive force-carrying particles, like the W boson, because that’s how we originally discovered it,” said scientist Patty McBride from the U.S. Department of Energy’s Fermi National Accelerator Laboratory, which supports the research of hundreds of U.S. scientists on the CMS experiment.

“Now we’re trying to understand its relationship with fermions.”

Fermions are particles that click together to form the invisible scaffolding inside atoms. Bosons, on the other hand, are the physical manifestation of forces and perform tasks such as gluing fermions together.

The Higgs field is like an endless ocean through which all matter swims. Some particles are like sponges and sop up mass as they lumber along, while others are as sprightly as tiny minnows and dart right through. The Higgs theory explains why some particles are massive while others are not. As not all predictions of the Higgs theory have been experimentally tested yet.

In June 2014, scientists on the CMS experiment published a paper in Nature showing that the Higgs boson has a relationship with fermions by measuring the rate at which it decays into tau leptons, a heavier cousin of the electron. Later, both the CMS and ATLAS experiments found evidence of the Higgs boson decaying into bottom quarks. Now, scientists are tackling its relationship with the top quark.

“The relationship between the Higgs and the top quark is particularly interesting because the top quark is the most massive particle ever discovered,” McBride said. “As the ‘giver of mass,’ the Higgs boson should be enormously fond of the top quark.”

Because the top quark is much more massive than the Higgs boson, it’s impossible for a Higgs boson to decay into a pair of top quarks. Luckily, there is another way to measure how strongly the Higgs boson couples to top quarks: looking for the rare case of simultaneous production of top quarks and a Higgs boson.

“Higgs boson production is rare – but Higgs production with top quarks is rarest of them all, amounting to only about 1 percent of the Higgs boson events produced at the LHC,” said Chris Neu, a physicist at the University of Virginia who worked on this analysis.

In a paper published today in the journal Physical Review Letters, scientists on the CMS experiment report observing a statistically significant abundance of events in which the Higgs boson is produced in association with two top quarks. The CMS result for this rare Standard Model process with a significance of 5.2 sigma constitutes the first observation that exceeds the 5 sigma threshold physicists require. The ATLAS experiment has also submitted a paper on the same phenomenon for publication.

“A top quark decays almost exclusively into a bottom quark and a W boson,” Neu said. “The Higgs boson, on the other hand, has a rich spectrum of decay modes, including decays to pairs of bottom quarks, W bosons, tau leptons, photons and several others. This leads to a wide variety of signatures in events with two top quarks and a Higgs boson. We pursued each of these and combined the results to produce our final analysis.”

Exploring the Higgs boson’s relationship with the top quark further could also be a possible window to new physics, according to Fermilab Deputy Director Joe Lykken.

“Pinning down this coupling will tell us a lot about the behavior of the Higgs and how it might also interact with other particles we haven’t discovered, like dark matter,” Lykken said. “Deeply understanding how the Higgs interacts with known particles could help lead us to physics beyond the Standard Model.”

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