This could be it. The Large Hadron Collider finally has enough data to explore every nook and cranny where the elusive Higgs boson could be hiding. LHC physicists will announce the results of their latest hunt on Tuesday at CERN in Switzerland.
What if they find nothing? New Scientist takes a look at alternatives to the Higgs.
What is the Higgs boson?
It is the last undiscovered member of
the standard model of particle physics, the leading theory describing
how particles and forces interact. The mysterious particle is thought to
give all other particles mass, but the standard model can't predict
what the Higgs itself weighs.
Where might the Higgs be hiding?
The Higgs may be produced fleetingly
when particles smash into each other at high speeds, and for years
physicists have been looking for evidence of it at various particle colliders.
They have gradually ruled out its existence at different masses, but
there is still a narrow mass range, between 115 and 141
gigaelectronvolts, where the simplest version of the Higgs could take refuge.
What will LHC physicists report next week?
Rumour has it they have found hints of the Higgs
at a mass of 125 gigaelectronvolts, about 133 times the mass of a
proton. What is known for sure, though, is that researchers from the
LHC's main detectors, ATLAS and CMS, will separately present
the past year's worth of data from the proton collider. That represents
more than 300 trillion high-speed particle collisions, more than twice
the amount of data reported at a conference in August.
That is still not enough data to be able to rule the Higgs definitively
in or out, but it should be enough to show hints of the Higgs if it
exists in the mass range that had previously not been scrutinised.
What if there is still no sign of the Higgs?
This time, if nothing materialises,
physicists will really start giving up. "If we witness a lack of events
in the full mass range, then clearly we will start disfavouring the
presence of the standard model Higgs boson in LHC data," says CMS
spokesperson Guido Tonelli.
"To really exclude it we would need additional data. But if in this
amount of data we don't see any indication that something is happening,
the most likely hypothesis is that we have to look for another
solution."
Are there other solutions?
"I think there are alternatives to the Higgs," says Nobel laureate Steven Weinberg
of the University of Texas at Austin, who, together with Sheldon
Glashow of Boston University and Abdus Salam of Imperial College London,
wrote the standard model in the 1960s. Giving up on the Higgs boson
opens the door for more exotic kinds of physics, including extra
particles and extra forces.
Do we need a Higgs boson to give things mass?
No, says theorist Matt Strassler of
Rutgers University in New Jersey. The Higgs boson is just a ripple in
the so-called Higgs field, which is really what is thought to give all
other particles mass. "The poor Higgs field labors in obscurity,
protecting the universe from catastrophe but getting none of its
deserved credit," Strassler writes in his blog.
Physicists are only looking for the
Higgs particle because it is the easiest way to access the field. If
they don't see it, then it suggests the field is different from the one
predicted by the standard model. Normally, particles in fields are like
ripples in ponds – photons are ripples in the electromagnetic field, for
example. But if the field is more like molasses than water, then the
ripples die away too quickly for us to detect.
That means matter might get its mass
from a thick Higgs-like field that has no associated particle. To get
such a goopy field, theorists need to add in more exotic possibilities –
such as new particles or forces of nature. "You can't get the situation
where there's no Higgs particle there unless you add something else,"
Strassler told New Scientist.
What about more exotic possibilities?
The existence of a new force, called technicolour,
could also give particles mass without the need for a Higgs boson.
Technicolour would act like a heavy-duty version of the strong nuclear
force, which binds quarks together in the nuclei of atoms. The
technicolour force would fill space with pairs of still more new
particles, which would form a soup through which other particles would
travel, gaining mass in the process.
"That would be an outstanding
alternative if the Higgs isn't there," Weinberg says. "In that case
there would be a whole host of other particles, probably at higher
energy, that the LHC might discover. But it wouldn't find the Higgs.
There wouldn't be a Higgs, in the usual sense."
Are there even more exotic ideas?
The existence of a fourth dimension of
space, beyond the three we experience, could explain why particles have
different masses – a fact that is usually attributed to the Higgs
boson.
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