Thank you to Squarespace for Supporting PBS. Itās the job of physicists to worry about
numbers, but thereās one number that physicists have stressed about more than any other. That number is 0.00729735256 - approximately
1/137. This is the fine structure constant, and it
appears everywhere in our equations of quantum physics, and weāre still trying to figure
out why. The fine structure constant, designated as
the greek letter alpha, just looks like one of the many constants of natureĀ
that power our laws of physics. Like the speed of light, the gravitational
constant, or Planckās constant. But thereās something so weird and so compellingĀ
about this number that many of the founders of quantum mechanics obsessed over it. Paul Dirac called it āthe mostĀ
fundamental unsolved problem in physics.ā Wolfgang Pauli said, āWhen I die my first
question to the Devil will be: What is the meaning of the fine structure constant?ā Even Richard Feyman pondered its mysteries
his entire life. In 1985 he wrote that "all good theoreticalĀ
physicists put this number up on their wall and worry about it." But what is it about this one number that
makes it the worthy subject of the obsession of savants? Before we get to that, let me tell you the
story of its discovery. As with much of quantum mechanics, it startedĀ
with us watching the light produced as electrons flicked between energy levels in atoms. This process results in the emission of photonsĀ
of specific energies that we observe as spectral lines - sharp peaks in the light observed
when we break it up into a spectrum of different wavelengths. For example this is the spectrum of Hydrogen. Hydrogen atoms only emit light with these
specific energies. Other elements have other spectral lines. Explaining spectral lines was a major driverĀ
of the development of quantum mechanics, and one of its first great successes, first withĀ
the Bohr model explaining hydrogen lines, then the Schrodinger equation for heavier
elements. But there was a problem. As our measurement apparatus improved, we sawĀ
that the single spectral lines were actually a little off the calculated values, and moreoverĀ
each single line was revealed to be composed of two lines at almost butĀ
not quite identical energies. It was Arnold Sommerfeld who managed to explainĀ
the discrepancy by including the effects of Einsteinās still-new relativity, as well
as the fact that the energy levels of electrons with opposite spins are separated slightly
by their interaction with their own orbital magnetic fields. Sommerfeld found something peculiar: thatĀ
the difference in energy between the fine lines was always a multiple of one particularĀ
number: the square of the charge of the electron, divided by four times pi, the permittivity
of free space, Planck's constant and the speed of light. OK, big deal. We see combinations of these sorts of importantĀ
constants throughout the laws of physics. But the weird thing with this particularĀ
combination is that it has no units. How can that be? The charge of the electron is in Couloumbs,Ā
the speed of light in meters per second, vacuum permittivity and Planck's constant
also have their units. But when you bring these together all units
completely cancel out. Weāre left with just a number - a pure number. This number just happens to be 1/137.035999,
the fine structure constant. If this number only appeared in the formulaĀ
for the fine structure splitting of spectral lines it would be just a fun oddity, except
this started to show up everywhere. For example, the repulsive energy between
two electrons is 137 smaller than a photon with wavelength equal to theĀ
distance between the electrons. And the orbital speed of an electron in the
ground state of the Bohr model of the hydrogen atom is 137 slower than the speed of light. And the energy of that ground state electronĀ
is smaller than the rest mass energy of the electron by a factor of 137 squared. And thatās just the tip of the iceberg for
the appearances of the fine structure constant in the laws of physics. Thereās no obvious reason that these variousĀ
ratios of properties should all work out to be 1/137, or 137 to some power. Itās clear the number is trying to tell
us something important about the universe, and now more than 100 years after SommerfeldĀ
discovered the structure constant, Iād like to tell you what it means. Except ā¦ I canāt, because we still donāt
know. But we do at least have a few ideas. To explore them, let's talk about couplings. Whenever two particles get close to each otherĀ
there's a chance they will interact, and they can interact in many different ways, which
we can visualize with Feynman Diagrams. We have an episode about those if youāre
curious. These diagrams are used toĀ
add up the probabilitiesĀ Ā of particles interacting by all the different ways that interaction could happen. Those probabilities depend on many things,Ā
like the particlesā positions and momenta, spins, charges, masses, etc. These factors multiply a sort of base probabilityĀ
to make the interaction more or less likely. That base probability comes from the coupling
constant or coupling strength for the interaction. And thatās exactly what theĀ
fine structure constant is:Ā Ā itās the coupling strength of the electromagnetic force. The square of alpha is the base probability
that an electron will emit or absorb a photon, or in the case of two electrons interacting by,Ā
say Feynman diagrams - itās the base probability at each vertex, each interaction between electronĀ
and virtual photon, adjusted by all these other parameters I mentioned. So the Fine Structure Constant sets theĀ
"strength" of the electromagnetic force. The more chance of interaction between theĀ
electron and electromagnetic fields, the more of an EM disturbance each electron will make. So itās starting to make sense why the fine
structure constant appears in all of these formulas that depend on the electromagnetic force. But the big questions still remains: why doesĀ
alpha take on the value that it does, and why does this specific combination of other fundamentalĀ
constants come out to be exactly alpha? When I say that alpha takes on a specific
value, Iām not telling you everything. Sometimes it doesnāt. In fact the fine structure constant isnāt
as constant as it sounds. It changes with the energy of the interaction. The higher the energy, the larger the constant. In the insane energies right after the Big
Bang, the coupling constant for the EM field - which was then joined with the other forces,Ā
would have been close to 1, but it quickly dropped to lower values as the energyĀ
dropped and the forces separated. Weāre now at the bottom of the energy scale,Ā
and the fine structure constant has bottomed out at 1/137.035999. But thereās no reason that we know of thatĀ
it shouldnāt have dropped all the way to zero rather than stopping at this minimum value -Ā
however we should be glad of this fact, because an alpha=0 would mean no electromagnetism,Ā
and that would mean no fridge magnets, among other inconveniences like no atoms. And actually weāre luckier than you think. This constant sets the size of atoms - a largerĀ
value means electrons would be closer to nuclei, making them more tightly bound and lessĀ
able to participate in chemical bonds. A smaller value would mean electrons were
less tightly bound, making atoms and molecules less stable. Itās been estimated that if the fine structureĀ
constant were just a few percent different, carbon would never have formedĀ
inside stars, making life impossible. We donāt know why our universeĀ
ended up with this particularĀ Ā value for the fine structure constant or many of the other fundamental constants. Many physicists believe that these constantsĀ
were set more or less randomly at the beginning of the universe. It would be surprising that they landed on
just the right values to allow for the formation of life - unless of course there are many,
many universes with different values for the constants. Then itās not surprising at all that we
find ourselves in one of the ones capable of producing us. Weāve talked about thisĀ
anthropic argument in the past. But the fact that the fine structure constantĀ
has such a convenient value isnāt the weirdest thing about it. The weirdest thing is that itās dimensionless. Imagine you were able to send a very short
message to an alien civilization. Just a handful of bits - enough to encode
one number. What number would you choose to ensure theyĀ
knew that the message came from an intelligent species? You could try the various constants of natureĀ
to demonstrate that you knew advanced physics. The problem is, most of these constantsĀ
require you to choose units of measurement. Transmit, say, the value for the speed of
light - 299,792,458 m/s, and you also have to explain what a meter and a second are. Try the gravitational or Planckās constant
and you also have to define the kilogram. Thereās no way for the alien civilization
to recognize these numbers without knowing our units for distance, time, mass, electric
charge, etc. But the fine structure constant is unitless. Itās equal to 1/137-ish for everyone in
the universe. Even if you just transmit the number 137,
those aliens are going to realize that somethingās up. Thatās handy for interstellar communication,
but it also tells us thatās something's -seriously- up with the fine structure constant. Being unitless on its own isnāt something special. We can come up with all sorts of unitless
values - just take the ratio between two things with the same units, like the ratio of theĀ mass of the electron andĀ
proton, or the coefficient of friction of an inclined plane. But these things donāt pop up in all these
unexpected places like the fine structure constant does. So what do we make of this number that is
both unitless and ubiquitous. Letās start by thinking about the similarly
prolific constants of nature - the ones that actually have units. Those units tell us a lot about what those
constants mean. They tell us that the constants of nature
represent relationships. For example, the speed of light is the translationĀ
factor between the dimensions of space and time in relativity; itās also the relationshipĀ
between mass and energy in Einsteinās famous equation. The gravitational constant is the relationshipĀ
between mass, distance, and gravitational force, Planck's Constant is the relationshipĀ
between the uncertainty in measuring position and velocity. The list goes on. The relationship is defined by the units of
the constant. But without any units, it's not immediately
clear what kind of relationship the Fine Structure Constant represents. So hereās an idea: perhaps this odd littleĀ number represents a relationshipĀ
between relationships. If the other constants of nature tie various
physical parameters together, perhaps the fine structure constant is what ties those
constants together. Think about it this way - if the constants
of nature were set randomly at the big bang, and were set independently to each other -Ā
then we wouldnāt necessarily expect there to be any one way of combining themĀ
thatās particularly special. Sure, you could find a combo where the unitsĀ
cancel out - but that combo wouldnāt necessarily have physical significance. The fact that this canceling gives the fine
structure constant, and the fine structure constant also represents the relationship
between many real, physical aspects of the universe, seems to be telling us something. It hints at a connection between the other
fundamental constants - perhaps pointing to an underlying common mechanism that set theĀ
values for the constants at the Big Bang. Or perhaps it hints at a deeper connectionĀ between the properties ofĀ
the elementary particles, like the mass and charge of the electron. Finally, it could be that the fine structure
constant is not a physical constant, but a mathematical one, like pi, but perhaps we
haven't realized this is the case because our mathematics are not advanced enough yet This is pretty speculative, but the specialness ofĀ
the fine structure constant warrants speculation. And weāve been speculating on this problemĀ
for a century as this funny little recurring number popped up again and again inĀ
our studies of the subatomic world. Back to Richard Feynman one last time. He called the fine structure constantĀ
āone of the greatest damn mysteriesĀ of physicsā and Poetically mused that āthe hand of God wroteĀ
that number, and we don't know how He pushed the pencil.ā In other words, to build a universe it may
be that only one number needs to be decided in the beginning and from it allĀ
other constants naturally follow. And perhaps that number was 1/137, the fineĀ
structure constant - whose value sets the rules of this particular space time. Thank you to Squarespace for Supporting PBS. Squarespace is a websiteĀ
building and hosting company. With Squarespace, you can connect with yourĀ
audience and generate revenue through gated, members-only content. Users can manage members,Ā
send email communicationsĀ Ā and leverage audience insights all in one platform. Users can also create community with a SquarespaceĀ
website through its fully integrated commenting system that supports threadedĀ
comments, replies and likes. Squarespace extensions helpĀ
users manage inventory,Ā products and streamline bookkeeping. With Squarespace, you can display social mediaĀ
posts on your websites and push website content to your preferred social accounts. Go to Squarespace.com for a free trial.
Love PBS Space Time.
Posting Space Time here is lowkey cheating, I'm sure of it š
So is this why Rick is from c-137?
interesting, thanks for sharing it here
This whole time I thought it was 42
Was very hard to follow. I love their content though and I try to watch most of their videos.