When researchers at the Large Hadron Collider discovered the elusive Higgs particle in 2012, it was a landmark for particle physics. It solved a very thorny problem, validating and allowing the Standard Model of particle physics to hold. But, as is often the case with new discoveries, while some questions were neatly answered, others arose. And for the Higgs boson, one of those questions is its mass. According to predictions, the particle ought to be around three times heavier than the 125 gigaelectronvolts it is.
We're not sure why
it isn't heavier, but a new paper lays out a fascinating solution. According to
physicists Raffaele Tito D'Agnolo of Université Paris Saclay in France and
Daniele Teresi of CERN, the problem can be resolved if, at the time of
the Big Bang, the Universe consisted of many universes – a
multiverse. Not only do the physicists' calculations solve the mass of the
Higgs boson, they also solve a seemingly unrelated problem in the Standard
Model: the preservation of symmetry in the strong
force that binds the elementary particles that form all normal matter.
The team's model
starts the Universe as a multitude of universes. Each universe in this
multiverse has a different mass for the Higgs boson – some quite heavy, and
some very light. Then, the physicists calculated how these universes would
evolve over time. They found that universes with heavier Higgs bosons became unstable and collapsed very quickly in a
"big crunch", in a fraction of a second.
The universes with
lighter Higgs bosons survived. Under this scenario, our Universe emerged as
perhaps the sole survivor of the catastrophic multiverse crunching, with a very
light Higgs boson. Under this model, something curious emerged. The strong
force is one of the fundamental forces of the Universe. It binds together
fundamental particles called quarks into
protons and neutrons and then binds those protons and neutrons into atomic
nuclei. So it's pretty important for the continued existence of, well,
everything.
The theory that
describes the strong force is called quantum chromodynamics. Under most models
of quantum chromodynamics, strong atomic forces don't need to conform to
something called charge-parity symmetry, or CP symmetry; yet for some
reason, they do. This is known as the strong CP problem. D'Agnolo
and Teresi found that symmetric strong interactions also contribute to
preventing a crunch. So a combination of a light Higgs boson and CP symmetry in
the strong force could have contributed to the long-term survival of our
Universe when others winked back out of existence.
It's all, of course, very theoretical, and this is just one of many possible explanations for the mass of the Higgs boson. But it offers avenues of exploration for helping to solve some of the other outstanding mysteries of our Universe.
"Our model stands out because it is simple, generic, and it solves these two seemingly unrelated puzzles at once," Teresi said. "And it predicts distinctive features in data from experiments that aim to search for dark matter or for an electric dipole moment in the neutron and other hadrons."
Probing the Higgs
boson is not an easy task because it has a lifespan of about one-septillionth
of a second before it decays into less massive particles. Physicists seek to
understand the Higgs boson studying these less massive particles, but it's
painstaking. Future experimental work should allow tests of the team's theory
since their work also predicted the existence of a new particle. The Large
Hadron Collider is due to be fired up again later
this year, after being shut down at
the start of 2019 for upgrades. It will be fascinating to see what
emerges.
Meanwhile, the research has been published in Physical Review Letters.