Вадим Дудченко
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The Higgs boson is peculiar in many respects. Like most other elementary particles, it is unstable and lives only for an extremely short time, 1.6*10-22 seconds, according to the Standard Model of particle physics. The experimental measurement of the particle’s lifetime is very important: it allows us to learn about the strength of its interaction with other particles and provides a window to peek into physics beyond the current theory. In a new study, physicists from the Compact Muon Solenoid (CMS) Collaboration at CERN’s Large Hadron Collider (LHC) report a value for the particle’s lifetime that has a small enough uncertainty to confirm that the Higgs boson does have such a short lifetime.

A Higgs boson candidate transforming into four muons (red lines). Image credit: CERN.

Measuring the Higgs boson’s lifetime is high on the wish list of particle physicists, because an experimental value of the lifetime would allow them not only to better understand the nature of the particle but also to find out whether or not the value matches the value predicted by the Standard Model of particle physics.

A deviation from the prediction could point to new particles or forces not predicted by the Standard Model, including new particles into which the Higgs boson would decay.

But it isn’t easy to measure the Higgs boson’s lifetime. For one, the predicted lifetime is too short to be measured directly.

A possible solution entails measuring a related property called the mass width, which is inversely proportional to the lifetime and represents the small range of possible masses around the particle’s nominal mass of 125 GeV.

But this isn’t easy either, as the predicted mass width of the Higgs boson is too small to be easily measured by experiments.

In addition to being produced with a mass equal or close to its nominal value, a short-lived particle such as the Higgs boson can also be produced with a much larger mass than the nominal value, although the odds of this happening are lower.

This effect — and in fact the mass width of the particle as well — is a manifestation of a quantum quirk known as Heisenberg’s uncertainty principle, and a comparison between the production rate of these large-mass (off-shell) Higgs bosons with that of the nominal or close to nominal (on-shell) Higgs bosons can be used to extract the Higgs boson’s mass width and therefore its lifetime.

Using this method, the physicists from the CMS Collaboration obtained the first-ever evidence for the production of off-shell Higgs bosons.

In the study, they analyzed data collected by the CMS experiment during the second run of the LHC, specifically data on Higgs bosons transforming into two Z bosons, which themselves transform into four charged leptons or two charged leptons plus two neutrinos.

From their result, which has only a 1 in 1,000 chance of being a statistical fluke, they obtained a Higgs boson’s lifetime of 2.1*10-22 seconds.

This value, the most precise yet, aligns well with the Standard Model prediction and confirms that the particle does indeed have a tiny lifespan.

“Our result demonstrates that off-shell Higgs-boson production offers an excellent way to measure the Higgs boson’s lifetime,” said Dr. Pascal Vanlaer, a member of the CMS Collaboration.

“And it sets a milestone in the study of the properties of this unique particle.”

“The precision of the measurement is expected to improve in the coming years with data from the next LHC runs and new analysis ideas.”

The findings were published on the CERN CDS information server.


CMS Collaboration. 2021. Evidence for off-shell Higgs boson production and first measurement of its width. CMS-PAS-HIG-21-013


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