Misunderstanding about measuring the spin of the electron

In summary, the conversation discusses a conceptual problem in quantum physics regarding the measurement of electron spin. The process involves aligning the spin of the electron and measuring it along the z-axis, which can result in a photon being emitted. The measurement causes the electron to be thrown into an eigenstate, but there is confusion about the state it is thrown into after the initial measurement. After further discussion, it is clarified that the measurement always results in a 100% spin-up or spin-down state, depending on the initial alignment of the electron. The conversation also references the Stern-Gerlach experiment and the concept of probability collapsing in measurement.
  • #1
micromass
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Hello,

I have been researching a bit of quantum physics, and I have encountered a conceptual problem.

Basically, we have an electron whose spin is aligned along some axis, and we wish to measure the spin along the z-axis. So what we do, is that we put the electron between two magnets. This automatically aligns the spin of the electron so that the spin is pointing up. If the spin was originally pointing up, then no photon is emitted. If the spin was originally pointing down, then a photon is emitted. If the spin was pointing in an arbitrary direction, then a photon can or can not be emitted depending on a probability. Is this correct so far?

However, after the measurement, the electron is thrown into one of the eigenstates. So if I measure the spin being up, then the electron is thrown into the state where the spin is up. And if I measure the spin being down, then the electron is thrown into the case where the spin is down. OK?

Here is my problem: suppose that the original alignment of the electron is such that the spin is down. Then measuring the spin will emit a photon (with probability 1). And this causes the spin to be realigned in the up-direction.
However, after the measurement, they say that the electron is thrown into the state where the spin is down. Aren't these two statements contradictory?? How does the electron leave the experiment?

Thanks for your time :smile:
 
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  • #2
Hmm, I'd say the electron is thrown into the state where the spin is down before the flip.
The electron leaves the experiment spin-up.

Note that a probability function also has time as a parameter.
The measurement collapses the probability function.
 
  • #3
Thank you ILS! This is a possibility that occurred to me too. But wikipedia says:

When the spin of this particle is measured with respect to a given axis (in this example, the x-axis), the probability that its spin will be measured as [itex]\hbar \over 2[/itex] is just [itex]\left\vert \langle \psi_{x+} \vert \psi \rangle \right\vert ^2[/itex]. Correspondingly, the probability that its spin will be measured as [itex]-\hbar \over 2[/itex] is just [itex]\left\vert \langle \psi_{x-} \vert \psi \rangle \right\vert ^2[/itex]. Following the measurement, the spin state of the particle will collapse into the corresponding eigenstate. As a result, if the particle's spin along a given axis has been measured to have a given eigenvalue, all measurements will yield the same eigenvalue (since [itex]\left\vert \langle \psi_{x+} \vert \psi_{x+} \rangle \right\vert ^2 = 1[/itex] , etc), provided that no measurements of the spin are made along other axes (see compatibility section below).

Doesn't this section indicate that if we enter the measurement as spin-down, that we leave the measurement spin-down??

I mean, if the experiment changes my spin-down to spin-up, why do the subsequent experiments also measure spin-down??

I've read about the Starn-Gerlach experiment and I understand that perfectly. But somehow I think my explanation:

Basically, we have an electron whose spin is aligned along some axis, and we wish to measure the spin along the z-axis. So what we do, is that we put the electron between two magnets. This automatically aligns the spin of the electron so that the spin is pointing up. If the spin was originally pointing up, then no photon is emitted. If the spin was originally pointing down, then a photon is emitted. If the spin was pointing in an arbitrary direction, then a photon can or can not be emitted depending on a probability.

must be wrong.

For the record, I've got this from the Susskind lectures. Here is a short summary: http://www.lecture-notes.co.uk/susskind/quantum-entanglements/lecture-2/electron-spin/
 
  • #4
Or is the thing that the wikipedia article is talking about a different experiment than mine??
That is: my experiment should change spin-down to spin-up. But the wikipedia article might use something like Starn-Gerlach which keeps the spin-down.

That would be a resolution, since then ILS's explanation that it is thrown into the state before the flip is most likely valid.
 
  • #5
As far as I can tell, the wikipedia section you refer to says nothing about flipping.
It only says that up has a certain probability and down has a certain probability and it shows what the bra-ket notation for this is.
Furthermore it says that once you measure it, the probability collapses.
It doesn't say to which state it collapses nor from which state it came from.
Nor does it refer to the Stern-Gerlach experiment.
 
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  • #6
I like Serena said:
As far as I can tell, the wikipedia section you refer to says nothing about flipping.
It only says that up has a certain probability and down has a certain probability and it shows what the bra-ket notation for this is.
Furthermore it says that once you measure it, the probability collapses.
It doesn't say to which state it collapses nor does it refer to the Stern-Gerlach experiment.

Doesn't the wikipedia article state that the particle will collapse to the corresponding eigenstate AFTER the measurement. And that all following measurements will yield the same value??

Or am I reading too much into this?

I am referring to Stern-Gerlach, because the wikipedia article doesn't mention how the measurement is made. Their measurement method might be different from what I mentioned in my OP.
 
  • #7
It holds true for *any* measurement, or more accurately, for any possibility of a measurement.

When you measure the electron in your experiment, you effectively always measure it as up.
Or you could say you measured it as down since it emitted a photon, after which it was flipped up, after which the probability function is still 100% up.
 
  • #8
Note that if you reuse your electrons after making them all spin-up, and you put them in a reverse magnetic field, *every* electron will emit a photon.

After that all electrons will be 100% spin-down.
 
  • #9
OK, it makes sense now. Thanks a lot!
 
  • #10
micromass said:
Basically, we have an electron whose spin is aligned along some axis, and we wish to measure the spin along the z-axis. So what we do, is that we put the electron between two magnets. This automatically aligns the spin of the electron so that the spin is pointing up.
That would be no measurement of the initial state, but a preparation of the |up> state. This isn't what's happening in the SG experiment. There, in order to measure the ratio of |up> and |down> of your intial state, you introduce a spatial separation.

To do this, you use a magnetic field gradient. The potential energy of a electron in a magnetic field is V = -µ B, where µ is the dipole moment associated with the electron's spin. Since force is F = -grad V, the direction of the force your particles are expierencing, depends on their spin orientation which leads to the spatial separation.
 
  • #11
kith said:
That would be no measurement of the initial state, but a preparation of the |up> state. This isn't what's happening in the SG experiment. There, in order to measure the ratio of |up> and |down> of your intial state, you introduce a spatial separation.

To do this, you use a magnetic field gradient. The potential energy of a electron in a magnetic field is V = -µ B, where µ is the dipole moment associated with the electron's spin. Since force is F = -grad V, the direction of the force your particles are expierencing, depends on their spin orientation which leads to the spatial separation.

Yes, it isn't the SG experiment. But it's another type of experiment outlined in the link I've put above. It may very well be that this type of experiment isn't valid or won't work, but I honestly don't know.
 
  • #12
micromass said:
Yes, it isn't the SG experiment. But it's another type of experiment outlined in the link I've put above. It may very well be that this type of experiment isn't valid or won't work, but I honestly don't know.
This is a question of what you want to do.

If you want to measure the spin in z-direction, your setup certainly doesn't work, because regardless of the initial state, you always end up in the |up> state. This is what I meant by calling it a "preparation". The SG experiment is able to tell you the ratio of |up> and |down> of an arbitrary initial state, so it really measures the spin in the z-direction.
 
  • #13
kith said:
This is a question of what you want to do.

If you want to measure the spin in z-direction, your setup certainly doesn't work, because regardless of the initial state, you always end up in the |up> state. This is what I meant by calling it a "preparation". The SG experiment is able to tell you the ratio of |up> and |down> of an arbitrary initial state, so it really measures the spin in the z-direction.

So Susskind was wrong??
 
  • #14
No, sorry for adding confusion!

I didn't read your posts carefully enough and thought that the final state of the electron was the measurement signal, while actually it is the detected photon. So it's true that you always prepare the electron in the |up> state, but it's not true that you can't measure the spin with the setup.

Susskinds experiment is easier to understand for laymen, but I would say it is less straightforward if you aim for the mathematical concepts, because it is not the final states of the particle itself that carry the information.
 
  • #15
kith said:
No, sorry for adding confusion!

I didn't read your posts very carefully and thought the final state of the electron was the measurement signal, while actually it is the detected photon. So it's true that you always prepare the electron in the |up> state, but it's not true that you can't measure the spin with the setup.

Susskinds experiment is easier to understand for laymen, but I would say it is less straightforward if you aim for the mathematical concepts, because it is not the final state of the particle itself that carries the information.

OK, that makes sense. Thank you a lot!
 
  • #16
Sorry for being late to the party. I didn't see this thread before. Not sure if everything has been sorted out already. I'll add a few comments anyway.

I would say that the setup that Susskind describes is not a spin component measurement, because the result is never "down". (It's either "up", or there's no result at all). This doesn't make Susskind wrong, because he only talked about "wanting" to measure the spin in a section titled "classical detection" that ends with the words "this does not happen". He's not saying that what he's describing is a measurement.

If a photon is detected, the electron is now prepared in the "up" state. If no photon is detected, the electron's spin state hasn't changed since it was prepared by another pair of magnets earlier.

If you run this experiment over and over on electrons that were all prepared in the same spin state, then you can figure out how the first pair of magnets were aligned. This isn't what one would normally consider a "measurement" in QM. A measurement is an interaction between the system and the measuring device that puts a component of the measuring device, that I'll call "the indicator component" here, into one of many possible final states labeled by numbers. The indicator component must appear as a classical object to a human observer, and its possible final states must be distinguishable. Otherwise, it wouldn't be of any use as an indicator. The number corresponding to the final state is considered the "result" of the measurement.

According to what I just said, the setup defines a measuring device with only one possible final state of the indicator component. I can't consider it a spin component measurement, since it doesn't have two possible final states. I also can't disqualify it from being considered a measurement just because we don't get a result every time we put a particle in its vicinity, because then an ordinary particle detector that simply goes "click" when it detects a particle wouldn't be considered a measuring device either. (A detection is considered a position measurement)
 
  • #17
Thanks a lot, Fredrik! It does make sense.

Fredrik said:
If a photon is detected, the electron is now prepared in the "up" state. If no photon is detected, the electron's spin state hasn't changed since it was prepared by another pair of magnets earlier.

This is interesting. So you say that if an electron comes in with a state like [itex]\frac{1}{\sqrt{2}}|\text{up}> + \frac{1}{\sqrt{2}} |\text{down}>[/itex] and if it doesn't emit a photon, then it remains in this state?? I thought it would change to [itex]|\text{up}>[/itex] regardless on if it emitted a photon or not.

I do see why this wouldn't be called an actual measurement.
 
  • #18
micromass said:
This is interesting. So you say that if an electron comes in with a state like [itex]\frac{1}{\sqrt{2}}|\text{up}> + \frac{1}{\sqrt{2}} |\text{down}>[/itex] and if it doesn't emit a photon, then it remains in this state?? I thought it would change to [itex]|\text{up}>[/itex] regardless on if it emitted a photon or not.
One last quick reply before I go to bed...

Yes, I believe that's accurate. This is what I'm thinking: A superposition like that is an eigenvector of [itex]\vec n\cdot\vec S[/itex], where [itex]\vec S=(S_x,S_y,S_z)[/itex] and [itex]\vec n[/itex] is a unit vector. I haven't calculated the direction of [itex]\vec n[/itex] in this example, but it should be in the xy plane. An electron has a magnetic moment [itex]\vec m[/itex] in the same (or is it opposite?) direction as [itex]\vec n[/itex]. So it's also in the xy plane. Classically, a magnetic moment m in a magnetic field B has potential energy [itex]U=-\vec m\cdot\vec B[/itex]. To rotate the magnetic moment from the xy plane to the z (or -z) direction will (at least in the classical theory) change the energy by an amount [itex]|\vec m|\,|\vec B|[/itex]. I expect the energy of the photon to correspond to this energy. So either the electron goes through unchanged, or it emits a photon. With perfect detection abilities, no photon detected should mean that the spin state hasn't been changed.
 
  • #19
Fredrik said:
One last quick reply before I go to bed...

Yes, I believe that's accurate. This is what I'm thinking: A superposition like that is an eigenvector of [itex]\vec n\cdot\vec S[/itex], where [itex]\vec S=(S_x,S_y,S_z)[/itex] and [itex]\vec n[/itex] is a unit vector. I haven't calculated the direction of [itex]\vec n[/itex] in this example, but it should be in the xy plane. An electron has a magnetic moment [itex]\vec m[/itex] in the same (or is it opposite?) direction as [itex]\vec n[/itex]. So it's also in the xy plane. Classically, a magnetic moment m in a magnetic field B has potential energy [itex]U=-\vec m\cdot\vec B[/itex]. To rotate the magnetic moment from the xy plane to the z (or -z) direction will (at least in the classical theory) change the energy by an amount [itex]|\vec m|\,|\vec B|[/itex]. I expect the energy of the photon to correspond to this energy. So either the electron goes through unchanged, or it emits a photon. With perfect detection abilities, no photon detected should mean that the spin state hasn't been changed.

OK, thanks a lot Fredrik! This was very helpful!

I'm studying a little bit of QM because I'm teaching a course on functional analysis soon. And I think I owe it to the students to at least give them a hint on why functional analysis is an important field. And perhaps I'll get them interested enough in the applications to actually get them to study it themselves :biggrin:

Thanks a lot!
 
  • #20
There's very little functional analysis associated with spin, because the spin states space is finite dimensional, isomorphic to C2s+1, where s is the spin value. Linear operators acting on finite dimensional spaces are not that interesting, not to me at least.
 
  • #21
dextercioby said:
There's very little functional analysis associated with spin, because the spin states space is finite dimensional, isomorphic to C2s+1, where s is the spin value. Linear operators acting on finite dimensional spaces are not that interesting, not to me at least.
But to be able to explain applications of functional analysis to QM, one should also know the basics of QM. And what better way to learn them than to study spin 1/2 systems?
 
  • #22
micromass said:
Hello,
...Basically, we have an electron whose spin is aligned along some axis, and we wish to measure the spin along the z-axis. So what we do, is that we put the electron between two magnets. This automatically aligns the spin of the electron so that the spin is pointing up. If the spin was originally pointing up, then no photon is emitted. If the spin was originally pointing down, then a photon is emitted. If the spin was pointing in an arbitrary direction, then a photon can or can not be emitted depending on a probability. Is this correct so far?
...

One very important aspect of spin is precession. If the external field is less then 45 degrees to the spin axis of the electron, then the electron only needs to precess (rotate its axis around the external field) and does not flip or emit a photon.

Also note that the axis of the electron is now "averaging" the same direction as the external field, due to the fact that it is precessing around the external field direction - hence the electron goes either "up" or "down" in a Stern-Gerlach type experiment.

This also gives a pretty clear idea of why the energy to flip has the square root of 2 in it. The electron doesn't flip until its axis is over 45 degrees.
 

1. What is the spin of an electron?

The spin of an electron is an intrinsic property of the particle, which means it does not come from its motion or interaction with other particles. It is a form of angular momentum and is often described as the electron "spinning" on its axis.

2. Why is measuring the spin of an electron important?

Measuring the spin of an electron is important because it is a fundamental property of the particle and plays a crucial role in many physical phenomena. It is also essential in understanding the behavior of atoms, molecules, and materials.

3. How is the spin of an electron measured?

The spin of an electron is measured using a technique called electron spin resonance (ESR) or electron paramagnetic resonance (EPR). This involves exposing the electrons to a magnetic field and observing the changes in their energy levels, which can then be used to determine their spin.

4. Can the spin of an electron be changed?

No, the spin of an electron is an intrinsic property and cannot be changed. It is a constant value for each electron and is not affected by external factors. However, the direction of the spin can be altered by applying a magnetic field.

5. What are some common misunderstandings about measuring the spin of an electron?

One common misunderstanding is that the spin of an electron is the same as its orbital motion, but in reality, they are two distinct properties. Another is that the spin of an electron is related to its actual physical rotation, when in fact it is a quantum mechanical property that cannot be visualized in the same way as a spinning object in classical physics.

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