Video Infoblog: Electrons DO NOT Spin

 

 

Quantum mechanics has a lot of weird stuff - but there’s thing that everyone agrees that no one understands. I’m talking about quantum spin. Let’s find out how chasing this elusive little behavior of the electron led us to some of the deepest insights into the nature of the quantum world.

 

 

Transcript

 

0:00

Quantum mechanics has a lot of weird stuff  - but there’s one thing that everyone agrees

0:04

that no one understands. I’m talking about quantum spin. Let’s find out how chasing

0:10

this elusive little behavior of the electron led us to some of the deepest insights into

0:15

the nature of the quantum world.

0:22

There’s a classic demonstration done in undergraduate physics courses - the physics

0:25

professor sits on a swivel stool and holds a spinning bicycle wheel. They flip the wheel

0:30

over and suddenly begin to rotate on the  chair. It’s a demonstration of the conservation

0:35

of angular momentum. The angular momentum  of the wheel is changed in one direction,

0:40

so the angular momentum of the professor has  to increase in the other direction to leave

0:44

the total angular momentum the same.

0:47

Believe it or not, this is basically the same experiment - suspend a cylinder of iron from

0:52

a thread and switch on a vertical magnetic field. The cylinder immediately starts rotating

0:57

with a constant speed. At first glance this appears to violate conservation of angular

1:02

momentum because there was nothing spinning  to start with. Except there was - or at least

1:08

there sort of was. The external magnetic field  magnetized the iron, causing the electrons

1:15

in the iron’s outer shells to align their spins. Those electrons are acting like tiny

1:21

bicycle wheels, and their shifted angular momenta is compensated by the rotation of

1:26

the cylinder.

1:26

That explanation makes sense if we imagine  electrons like spinning bicycle wheels - or

1:32

spinning anything. Which might sound fine because electrons do have this property that

1:37

we call spin. But there’s a huge problem: electrons are definitely NOT spinning like

1:42

bicycle wheels. And yet they do seem to possess  a very strange type of angular momentum that

1:48

somehow exists without classical rotation. In fact the spin of an electron is far more

1:53

fundamental than simple rotation - it’s a quantum property of particles, like mass

1:59

or the various charges. But it doesn’t just cause magnets to move in funny ways - it turns

2:05

out that quantum spin is a manifestation of a  much deeper property of particles - a property

2:11

that is responsible for the structure of all matter. We’ll unravel all of that over a

2:16

couple of episodes - but today we’re going to

2:18

Today we’re going to talk about what  spin really is and get a little closer to

2:22

understanding what this weird property of nature.

2:25

The experiment with the iron cylinder is called  the Einstein de-Haas effect, first performed

2:30

by, well, Einstein and de-Haas in 1915. It wasn’t the first indication of the spin-like

2:36

properties of electrons. That came from looking  at the specific wavelengths of photons emitted

2:41

when electrons jump between energy levels  in atoms. Peiter Zeeman, working under the

2:46

great Hendrik Lorenz in the Netherlands, found  that these energy levels tend to split when

2:52

atoms are put in an external magnetic field.  This Zeeman effect was explained by Lorentz

2:58

himself with the ideas of classical physics. If you think of an electron as a ball of charge

3:04

moving in circles around the atom, that motion  leads to a magnetic moment - a dipole magnetic

3:10

field like a tiny bar magnet. The different alignments of that orbital magnetic field

3:15

relative to the external field turns one energy level into three.

3:20

Sounds reasonable. But then came the anomalous  Zeeman effect. In some cases, the magnetic

3:26

field causes energy levels to split even further  - for reasons that were, at the time, a complete

3:31

mystery. One explanation that sort of works is  to say that each electron has its own magnetic

3:38

moment - by itself it acts like a tiny bar magnet. So you have the alignment of both

3:43

the orbital magnetic moment and the electron’s  internal moment contributing new energy levels.

3:48

But for that to make sense, we really need to think of electrons as balls of spinning

3:53

charge - but that has huge problems. For example, in order to produce the observed

3:57

magnetic moment they’d need to be spinning  faster than the speed of light. This was first

4:02

pointed out by the Austrian physicist Wolfgang  Pauli. He showed that, if you assume electrons

4:07

have a maximum possible size given by the best  measurements of the day, then their surfaces

4:12

would have to be moving faster than light to give the required angular momentum. And

4:17

that’s assuming that electrons even have a size - as far as we know they are point-like

4:21

- they have zero size, which would make the  idea of classical angular momentum even more

4:27

nonsensical. Pauli rejected  the idea of associating such  

4:31

a classical property like rotation to

4:33

the electron, instead insisting on calling it a “classically non-describable two-valuedness”.

4:40

OK, so electrons aren’t spinning, but somehow  they act like they have angular momentum. And this

4:47

is how we think about quantum spin now. It’s  an intrinsic angular momentum that plays into

4:52

the conservation of angular momentum like  in the Einstein de-Haas effect, and it also

4:57

gives electrons a magnetic field. An electron’s  spin is an entirely quantum mechanical property,

5:03

and has all the weirdness you’d expect from  the weirdest of theories. But before we dive

5:08

into that weirdness, let me give you one more  experiment that reveals the magnetic properties

5:13

that result from spin.

5:15

This is the Stern-Gerlach experiment - proposed  by Otto Stern in 1921 and performed by Walther

5:21

Gerlach a year later. In it silver atoms are fired through a magnetic field with a gradient

5:26

- in this example stronger towards the north  pole above and getting weaker going down.

5:31

A lone electron in the outer shell of the silver atoms grants the atom a magnetic moment.

5:37

That means the external magnetic field induces a  force on the atoms that depends on the direction

5:43

that these little magnetic moments are pointing  relative to that field. Those that are perfectly

5:48

aligned with the field will be deflected by the most - either up or down. If these were

5:54

classical dipole fields - like actual tiny bar magnets - then the ones that were only

5:59

partially aligned with the external field should be deflected by less. So a stream of

6:04

silver atoms with randomly aligned magnetic  moments is sent through the magnetic field.

6:10

You might expect a blur of points where the  silver atoms hit the detector screen - some

6:14

deflected up or down by the maximum, but most  deflected somewhere in between due to all

6:19

the random orientations. But that's not what’s  observed. Instead, the atoms hit the screen

6:25

in only two spots corresponding  to the most extreme deflections.

6:31

Let’s keep going. What if we remove the screen and bring the beam of atoms back together.

6:36

Now we know that the electrons have to be aligned up or down only. Let’s send them

6:41

through a second set of Stern-Gerlach magnets,  but now they’re oriented horizontally. Classical

6:48

dipoles that are at 90 degrees to the field would experience no force whatsoever. But

6:54

if we put our detector screen we see that the atoms again land in two spots - now also

7:00

oriented horizontally.

7:02

So not only do electrons have this magnetic  moment without rotation, but the direction

7:07

of the underlying magnetic  momentum is fundamentally quantum.  

7:11

The direction of this "spin" property

7:13

is quantized - it can only take on specific values. And that direction depends on the

7:18

direction in which you choose to measure it.  Here we see an example of Pauli's two-valuedness

7:24

manifesting as something like the direction  of a rotation axis, or the north-south pole

7:29

of the magnetic dipole.

7:30

But actually this two-valuedness is far deeper  than that. To understand why we need to see

7:37

how spin is described in quantum mechanics. It  was again Pauli who had the first big success

7:44

here. By the mid 1920s physicists were very  excited about a brand new tool they’d been

7:50

given - the Schrodinger equation. This equation  describes how quantum objects behave as evolving

7:56

distributions of probability - as wavefunctions.It  was proving amazingly successful at describing

8:03

some aspects of the subatomic world. But the  equation as Schrodinger first conceived it

8:08

did not include spin. Pauli managed to fix this by forcing the wavefunction to have two

8:14

components - motivated by this  ambiguous two-valuedness of electrons.  

8:20

The wavefunction became a very

8:21

strange mathematical object called a spinor,  which had been invented just a decade prior.

8:28

And just one year after Pauli’s discovery,  Paul Dirac found his own even more complete fix

8:34

of the Schrodinger equation - in this case to make it work with Einstein’s special

8:38

theory of relativity - something we’ve discussed  before. Dirac wasn’t even trying to incorporate

8:44

spin, but the only way the equation could be derived was by using spinors.

8:50

Now spinors are exceptionally weird and cool,  and really deserve their own episode. But

8:57

let me say a couple of things to give you a taste. They describe particles that have

9:01

very strange rotation properties. For familiar  objects, a rotation of 360 degrees gets it

9:07

back to its starting point. That’s also true of vectors - which are just arrows pointing

9:12

in some space. But for a spinor you need to  rotate it twice - or 720 degrees - to get

9:19

back to its starting state.

9:20

Here’s an example of spinor-like behavior. If I rotate this mug without letting go my

9:26

arm gets a twist. A second rotation untwists me.

9:30

We can also visualize this with a cube attached  to nearby walls with ribbons. If we rotate

9:35

the cube by 360 degrees, the cube itself is back to the starting point, but the ribbons

9:40

have a twist compared to how they started.  Amazingly, if we rotate another 360 - not

9:46

backwards but in the same direction - we get  the whole system back to the original state.

9:51

Another thing to notice is that the cube can  rotate any number of times, with any number

9:56

of ribbons attached, and it never gets tangled.

9:59

So think of electrons as being connected to  all other points in the universe by invisible

10:05

strands. One rotation causes a twist, two brings it back to normal. To get a little

10:11

more technical - the spinor wavefunction has  a phase that changes with orientation angle

10:17

- and a 360 rotation pulls it out of  phase compared to its starting point.

10:22

To get some insight into what spin really is,  

10:25

think not about angular momentum,  but regular or linear momentum.

10:30

A particle's momentum is fundamentally  connected to its position.

10:33

By Noter's theorem, the invariance  of the laws of motion to changes in

10:37

coordinate location gives us the law of the  conservation of momentum. For related reasons

10:43

in quantum mechanics position and  momentum are conjugate variables.

10:47

Meaning you can represent a particle wavefunction  in terms of either of these properties.

10:51

And by Heisenberg's uncertainty principle  

10:53

increasing your knowledge of one, means  increasing the unknowability of the other.

10:58

If position is the companion variable of momentum,  what's the companion of angular momentum?

11:05

Well it's angular position. In other  words the orientation of the particle.

11:09

So one way to think about the  angular momentum of an electron

11:12

is not from classical rotation,  

11:14

but rather from the fact that they  have a rotational degree of freedom

11:17

which leads to a conserved  quantity associated with that.

11:21

They have undefined orientation, but  perfectly defined angular momentum.

11:26

Some physicists think that spin is  more physical than this. Han Ohanian,  

11:31

author of one of the most used quantum textbooks.

11:34

shows that you can derive the right values of the  electron spin angular momentum and magnetic moment

11:39

by looking at the energy and charge  currents in the so called Dirac field.

11:44

That's the quantum field surrounding  the Dirac spinor aka the electron,  

11:49

imply that even if the electron

11:51

is point like, it's angular momentum can arise  from an extended though still tiny region.

11:57

However you explain it, we have an excellent  working definition of how spin works.

12:02

We say that particles described by spinors have spin quantum numbers that are half-integers

12:06

- ½, 3/2, 5/2, etc. The electron itself has spin ½ - so does the proton and neutron.

12:13

Their intrinsic angular momenta can only be observed as plus or minus a half times

12:19

the reduced Planck constant,  

12:20

projected onto whichever direction  you try to measure it. We call these

12:24

particles fermions. Particles that have integer  spin - 0, 1, 2, etc. are called bosons, and

12:31

include the force-carrying particles like the photon, gluons, etc. These are not described

12:36

by spinors but instead by vectors, and behave  more intuitively - a 360 degree rotation brings

12:42

them back to their original state.

12:44

This difference in the rotational  properties of fermions and bosons  

12:47

results in profound differences

12:50

in their behavior - it defines how they interact  with each other. Bosons, for example, are

12:55

able to pile up in the same quantum states, while fermions can never occupy the same state.

13:00

This anti-social behavior of fermions  

13:03

manifested as the Pauli Exclusion  Principle and is responsible

13:07

for us having a periodic table, for electrons  living in their own energy levels and for matter  

13:12

actually having structure. It’s the reason

13:14

you don’t fall through the floor right now. But why should this obscure rotational property

13:20

lead to such fundamental behavior? Well this  is all part of what we call the spin statistics

13:26

theorem - which we’ll come back to in an episode very soon.

13:30

Electrons aren’t spinning - they’re doing something far more interesting. The thing

13:35

we call spin is a clue to the structure of matter - and maybe to the structure of reality

13:40

itself through these things we call spinors - strange little knots in the subatomic fabric of

13:48

spacetime.

13:49

Last time we talked about the connection between  quantum entanglement and entropy - this was

13:54

a heady topic to say the least, but you guys had such incredibly insightful comments and

13:58

questions.

13:59

Joseph Paul Duffey asks whether entropy is  an illusion created by our observation of

14:04

isolated components within a "larger"  entangled system? Well the answer

14:08

is that entropy is sort of relative.  It's high or low depending on context. 

14:14

The air in a room may be perfectly mixed and

14:17

so considered “high” entropy. But if that room  is warm compared to a cold environment outside,

14:23

then the total room + environment is at a relatively low entropy compared to the maximum

14:28

- if you opened the doors and  let the temperature equalize.

14:32

Von Neumann entropy is different to thermodynamic  entropy in that it represents the information

14:37

contained in the system and extractable in principle, versus information that’s lost

14:42

to the system by entanglement with the  environment with the environment. On  

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the other hand, classical or  thermodynamic entropy represents

14:48

information that is hidden beneath the crude  properties of the system, but may in principle

14:53

be extracted. And yet von Neumann entropy has  a similar contextual nature. If your system

15:00

has no entanglement with the environment then  its von Neumann entropy is zero. But if you

15:04

consider a subsystem within that  system then that entropy rises.

15:09

Randomaited asks the following: If entropy only increased over time, which implies it

15:15

was at its minimum at the Big Bang, does that  mean there was no quantum entanglement at

15:20

the Big Bang? To answer this we’d need to know why entropy is so low at the Big Bang - and

15:26

that’s one of the central mysteries of the universe. But, I’ll give it a shot anyway.

15:31

So we can’t really talk about the t=0 beginning  of time, because that moment lost in our ignorance

15:36

about quantum gravity and inflation and whatever  other crazy theory we haven’t figure out

15:40

yet. But what we do know is that at some very,  very small amount of time after t=0, the universe

15:46

was extremely compact - which meant hot and  dense, and it was also extremely smooth. The

15:52

compact part is where the low entropy comes  from. The “gravitational degrees of freedom”

15:57

were almost entirely unoccupied. On the other  hand, the extreme smoothness meant that the

16:03

entropy associated with matter was extremely  high. Energy was as spread out as it could

16:08

get between all of the particles and the different  ways they could move. The low gravitational

16:13

entropy massively outweighed the matter entropy,  so entropy was low. That smoothness seems

16:20

to suggest the particles of the early universe  were already entangled - otherwise how did

16:25

they spread out their energy?

16:27

Chris Hansen makes the same point, asking if  the conditions of the Big Bang meant everything

16:33

started out entangled. You’d think so - but  that’s not necessarily the case. Remember

16:40

that von Neumann entropy is relative to the 

16:42

system you’re talking about,  and so is entanglement.

16:45

Let’s say you have a bunch of particles that are not entangled with each other but

16:49

are all entangled with another bunch of particles  somewhere else. If you ignore those other

16:53

particles then it seems like there’s no entanglement in the particles of the first

16:57

system.  

16:58

And yet those particles may have correlated  thermodynamic properties due to their mutual

17:03

connection to the outside. In the early universe, the extreme expansion of cosmic

17:07

inflation may have permanently separated entangled  regions, but left those regions with an internal

17:14

thermal equilibrium which does NOT require maximal  entanglement within the regions themselves.

17:20

In other words, the universe - or our patch of it - may have started out unentangled and

17:26

at low entropy, even if it was at thermal equilibrium.

17:29

Lincoln Mwangi also dropped some knowledge,  informing us that “The Cloud” - is actually

17:34

named after Dr, Shannon, the founder of the  field of information theory. As with many

17:39

of these things, the word has been corrupted  over time and is now routinely mispronounced.

17:44

This is very disrespectful, and I intend to write a series of op-eds to correct the matter.

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Right after we upload this video to the claude.