Physics is a wonderful way for people to understand
the world around them. It can explain how
birds fly, why ice freezes, what makes fire
glow, just to mention a few things.
Now, this doesn’t meant that the explanations
are always easy and clear. In fact, the explanations
can be downright murky for phenomena far from
the familiar.
Perhaps the two physics theories that are
the hardest to accept when you first encounter
them are Einstein’s theory of relativity
and quantum mechanics. The first one talks
about how moving clocks run more slowly than
stationary ones and how objects in motion
appear to shrink. The second one tells us
that no measurement is certain and that probability
reigns supreme in the subatomic world.
While I’d like to tell you that there is
some credible debate about these theories
and that that we scientists have somehow figured
out a way to return to the more intuitive
physics of the late 1800s, but that isn’t
true. The simple fact is that relativity and
quantum mechanics have been tested countless
times and they work. Like it or not, we have
to learn to accept these weird predictions
are just, simply, well, true.
However- and this might blow your mind- these
ideas are also about a hundred years old.
Frontier science has actually moved on. What
scientists currently think is even weirder
still.
So let’s review a bit what traditional quantum
mechanics is all about. It was invented in
the mid 1920s and it was exemplified by an
equation devised by Erwin Schrodinger, what
we now call Schrodinger’s equation. This
equation explained why electrons had only
certain energies and positions when they circled
an atom. At its very simplest, the equation
explained that an electron could be here or
there, but never here nor there.
That’s what “quantum” means. There are
certain, discrete things that are possible
and others that aren’t. The things that
were quantized could be mass, charge, position
or energy.
Now, Schrodinger’s equation was only a partial
quantum theory and it didn’t take into account
relativity. What it did was take a proton
and assume it was surrounded by a classical
electrical field. Remember that classical
fields are not quantized. They vary smoothly.
However, things changed in the late 1920s
when Paul Dirac started puttering around with
quantum mechanics. One thing he did was successfully
merge quantum mechanics and Einstein’s theory
of special relativity. Another thing he spearheaded
was to figure out a way to make a fully quantum
theory. He did this by finding a quantum formulation
of the electric field surrounding the proton.
We call this the “second quantization revolution.”
This just means that the electric field was
expressed quantum mechanically and that it
joined such things as a quantum description
of the location of matter, which was covered
by the first quantum revolution.
In the ensuing years, these ideas have been
generalized to cover all of the subatomic
forces, specifically the strong nuclear force,
the weak nuclear force and electromagnetism.
While each force has a different precise formulation,
they are all examples of what we now call
a quantum field theory or QFT.
Although each theory has its own interesting
peculiarities, I want to talk a little about
some general truths of all quantum fields.
In modern physics theory, one can picture
all subatomic particles as beginning with
a field. Then the particles we see are just
localized vibrations in the field.
So, according to quantum field theory, the
right way to think of the subatomic world
is that everywhere- and I mean everywhere-
there are a myriad of fields. Up quark fields,
down quark fields, electron fields, etc. And
the particles are just localized vibrations
of the fields that are moving around.
The idea can also explain how particles interact.
For example, suppose you have an electron
moving along. The electron is a localized
vibration of the electron field. If the electron
emits a photon, then the quantum field theory
way of looking at things says that some of
the energy of the electron field sets up a
localized vibration of a photon field which
then moves away.
So those are the essential features of quantum
field theory. Theoretical physics simply imagines
that ordinary space is full of fields for
all known subatomic particles and that localized
vibrations can be found everywhere. These
fields can interact with one another, like
two adjacent tuning forks. These interactions
explain how particles are created and destroyed-
basically the energy of some vibrations move
from one field and set up vibrations in another
kind of field.
Now, of course, actually calculating something
with this prescription is really, really very
difficult. The math can be pretty crazy. But
the basic idea is really very simple. If you
look around you and you have even the smallest
ability to think creatively, you can imagine
these vibrations everywhere you look. I don’t
know about you, but I think that’s an awfully
cool idea.
