The Higgs Boson Part I: What it is and why
it matters
Let's cut to the chase: as of July 4, 2012,
the Higgs Boson is the last fundamental piece
of the Standard Model of Particle Physics
to be discovered experimentally. "But," you
might ask, "why was the Higgs Boson included
in the Standard Model alongside well-known
particles like electrons and photons and quarks
if it hadn't been discovered back then in
the 1970s?" Good question. There are two main
reasons:
First, just like the electron is an excitation
in the electron field, the Higgs boson is
simply a particle which is an excitation of
the everywhere-permeating Higgs field. The
Higgs field, in turn, plays an integral role
in our model for radioactive decay, called
the weak nuclear force (in particular, the
Higgs field helps explain why it's so weak).
We'll talk more about this in a later video,
but even though weak nuclear theory was confirmed
in the 1980s, in the equations the Higgs field
is so inextricably jumbled with the weak force
that until now we've been unable to confirm
its actual and independent existence.
The second reason to include the Higgs in
the standard model is some jargony business
about the Higgs field giving all other particles
mass. But why does stuff need to be "given"
mass in the first place? Isn't mass just an
intrinsic property of matter, like electric
charge? Well, in particle physics…no. Remember
that in the Standard Model, we first write
down a mathematical "ingredients list" of
all the particles that we think are in nature
(and their properties). You can watch my "theory
of everything" video for a quick refresher.
We then run this list through a big fancy
mathematical machine, which spits out equations
that tell us how these particles behave.
Except, if we try to include mass as a property
for the particles on our ingredients list,
the math-machine breaks. Maybe mass was a
poor choice… but most particles we observe
in nature do have mass, so we have to figure
out some clever way of using ingredients that
will spit out mass in the final equations
without it being an input - kind of like how
you can let yeast, sugar and water ferment
into alcohol that wasn't there to begin with.
And as you may be thirstily anticipating,
the solution is to toss a yeasty Higgs field
in with the other ingredients of the Standard
Model, so that when we let the math ferment,
we get out particles that have mass! But this
model also brews up something we DIDN'T intend:
a solitary Higgs particle, the infamous boson.
And since the model works so well to explain
everything else, we figured it was pretty
likely that the lonely boson is right, too!
To summarize, the Higgs Boson is a particle
which is a left-over excitation of the Higgs
field, which in turn was needed in the Standard
Model to 1) explain the weak nuclear force
and 2) explain why any of the other particles
have mass at all. However, the boson is the
only bit of the Higgs field which is independently
verifiable, precisely because the other bits
are tangled up in the weak nuclear force and
in giving particles mass. The fact that the
Higgs Boson is so independent from the rest
of the Standard Model is why it's the last
piece of the puzzle to be discovered - and
if it turns out to be exactly what was predicted,
the Standard model will be complete.
The only problem is that we know that the
standard model ISN'T a complete description
of the universe (it entirely misses out on
gravity, for example). So to physicists, it
would be much more interesting AND helpful
if the Higgs boson turns out to be not quite
what we expect… then we might get a clue
as to how to reach a deeper understanding
of the universe. So even though we just made
a discovery, we can't sit back and relax.
We need a hint, Mr. Higgs.
Continued in Parts II and III