Two and a half years ago scientists used the
most complicated machine ever to solve one
of the greatest puzzles to vex the human race.
And then they went, “Yeah but what if we
kicked it up a notch?”
Greetings atom smashers, Julian here for DNews.
The Large Hardon Collider made headlines years
ago when it confirmed the existence of the
Higgs Boson.
This was huge news in the world of particle
physics because the discovery solved a few
quarks....
I mean quirks.
As we understand it, there are subatomic particles
that carry the fundamental forces (except
gravity, as far as we know) called bosons.
In order for the math to work, these bosons
should be massless.
And yet we actually observed some of them
and found that certain kinds of bosons did
indeed have mass.
To solve the problem it was proposed by Peter
Higgs and other researchers in the 60’s
that a field existed everywhere all the time,
and moving through this field gave bosons
and other particles their mass.
The math predicted that if the field was excited
by high energy collisions, you could jiggle
the field in just the right way to briefly
spring another particle together, and that
particle is what we call the Higgs Boson.
But scientists weren’t content to dust off
their hands on their lab coats and call it
a day.
No, they decided to build a 27 kilometer underground
loop of supercooled magnets and tubes and
cameras 5 stories high so they could take
pictures of protons smashing together at nearly
the speed of light, and they did it with no
guarantee that the Higgs Boson could be found
or even existed at all.
And you thought asking out your crush was
risky.
But when they first flipped the switch in
2008, there was a problem.
One measly connecting wire in the over 10,000
used for the superconducting magnets failed
and damaged the LHC.
When it was brought back online, it could
only run at half of its intended power.
And then they found the Higgs Boson anyway.
This machine answered one of the greatest
questions ever asked with one hand tied behind
it’s back.
But there’s more work to do.
You see the math doesn’t predict an exact
value for the Higgs, and if the Higgs boson
has certain masses it implies vastly different
things.
One possible mass equation suggests the Higgs
is 115 gigaelectronvolts over the speed of
light squared (GeV/c^2), which supports the
idea of supersymmetry, or more particles to
add to the standard model that we haven’t
found yet.
But the Higgs could also have a mass around
140 GeV, and that suggests a favorite theory
of sci fi, the multiverse.
A mass that high could lend credibility to
the idea that there are many universes with
Higgs bosons of different masses and ours
just happens to be a universe that has a higgs
field just right to keep everything stable.
So what is the actual mass of the Higgs boson?
About 125 GeV/c squaredSweet@.
So supersymmetry or multiverse?
Both?
We have no idea.
That’s why in March the LHC is coming back.
It’s here to kick butt and chew bubblegum,
and it’s all out of bubblegum.
It’s going to be twice as powerful with
tougher wiring.
It’ll have better cooling to keep it’s
superconducting magnets at 1.9 degrees above
absolute zero.
And it’s been had its cameras upgraded for
more precise measurement.
And when it spools up, no one knows what we’ll
find.
Supersymmetric particles?
Candidates for Dark Matter?
Nothing at all?
We’re just going to have to wait and see.
If bosons and fermions and quarks is all just
a bunch of gibberish to you, we have a video
on what all those mean - check this out:
