Why does it have to be like that?Demystifier said:I meant constructed in a sense I have constructed my operator, as a sum/integral over all possible single outcomes.
That is not what Coleman says. Look at the box on page 10.gentzen said:Let us look at the 4-dimensional Hilbert space for Demystifier's simplified scenario. On L is defined on the "corresponding" basis via
L |neutral_L, neutral_R⟩ = 0
L |ionized_L, neutral_R⟩ = |ionized_L, neutral_R⟩
L |neutral_L, ionized_R⟩ = |neutral_L, ionized_R⟩
L |ionized_L, ionized_R⟩ = 0
Now the Bohmian (or Zurek) wonders why we never observe a state
c2 |ionized_L, neutral_R⟩ + c3 |neutral_L, ionized_R⟩
L cannot answer that question. It can only tell us that we won't observe any of the states
c0 |neutral_L, neutral_R⟩ + c3 |ionized_L, ionized_R⟩
(for arbitrary complex coefficients c0 and c3).
Let us first agree on Demystifier's example. He thinks it generalizes to more complicated scenarios. And what Coleman says on page 10 is certainly more complicated.martinbn said:Why does it have to be like that?
That is not what Coleman says. Look at the box on page 10.
So that it can be compared with my argument, so if my argument is wrong I can see why it is wrong.martinbn said:Why does it have to be like that?
gentzen said:Let us first agree on Demystifier's example. He thinks it generalizes to more complicated scenarios. And what Coleman says on page 10 is certainly more complicated.
Which example is that? The one in post #48?Demystifier said:So that it can be compared with my argument, so if my argument is wrong I can see why it is wrong.
Yes. And if Demystifier agrees that his Hilbert space should have been (at least) 4 dimensional instead of 2 dimensional, then his example in some "suitably fixed" form (like the one I gave in #60).martinbn said:Which example is that? The one in post #48?
Well, no, it cannot be this Hilbert space. You need to include the observer or the aparatus.gentzen said:Yes. And if Demystifier agrees that his Hilbert space should have been (at least) 4 dimensional instead of 2 dimensional, then his example in some "suitably fixed" form (like the one I gave in #60).
I think I disagree. If there is exactly one scattered particle, then there is no state ##|{\rm neutral}_L,{\rm neutral}_R\rangle##, because such a state would correspond to zero scattered particles. Likewise, there is no ##|{\rm ionized}_L,{\rm ionized}_R\rangle##, because it would correspond to two scattered particles.gentzen said:Yes. And if Demystifier agrees that his Hilbert space should have been (at least) 4 dimensional instead of 2 dimensional,
Note that Coleman's operator L operates on the state of the cloud chamber |C⟩, not on the initial or scattered particle. L looks at the ionized atoms (or molecules), and has Eigenvalue +1 if there is at least one ionized atom and all ionized atoms lie approximately on a straight line.Demystifier said:I think I disagree. If there is exactly one scattered particle, then there is no state ##|{\rm neutral}_L,{\rm neutral}_R\rangle##, because such a state would correspond to zero scattered particles. Likewise, there is no ##|{\rm ionized}_L,{\rm ionized}_R\rangle##, because it would correspond to two scattered particles.
Fine, suppose that there are two atoms, one on the left and one on the right. And suppose that you observe that no atom is ionized. Would you conclude that you have found the system in some strange non-classical superposition? I wouldn't, instead I would conclude that there is no scattered particle in the chamber at all.gentzen said:Note that Coleman's operator L operates on the state of the cloud chamber |C⟩, not on the initial or scattered particle. L looks at the ionized atoms (or molecules), and has Eigenvalue +1 if there is at least one ionized atom and all ionized atoms lie approximately on a straight line.
So for your simplified example, you need at least one atom on the left side, and one atom on the right side. Otherwise you don't get anything analogous to the Mott-Coleman argument.
Maybe it should.martinbn said:Can you constructively discribe the Hilbert space of a human? Probably not, but that never stops you from using it in a general argument.
In the given setup, L is the measurement operator. So you don't observe indiviual atoms at all. You just observe L. And in the simple scenarios, L is build up from configurations that seem to allow a classical interpretation.Demystifier said:And suppose that you observe that no atom is ionized.
The individual ones do. But the actual quantum state that's prepared is not one of them. It's a linear superposition of all of them. And, by the argument that Coleman gives in the lecture, that linear superposition is also an eigenstate of L with eigenvalue +1. And that means that, if we make a measurement with L as the measurement operator, we should not see an individual straight line--we should see the whole superposition, because it's an eigenstate of L!gentzen said:L is build up from configurations that seem to allow a classical interpretation.
Not for Coleman. For him, the relevant Hilbert space is that of the dots.Demystifier said:Even though the dots are macroscopic, the relevant Hilbert space is 2-dimensional.
For Coleman, there are states ##|none\rangle## and ##|both\rangle##. And Coleman does not mean a superposition such as ##|up\rangle+|down\rangle## by this.Demystifier said:There are no states ##|none\rangle## (corresponding to no macroscopic dots seen at all) and ##|both\rangle##(corresponding to one macroscopic dots seen down and another macroscopic dot seen up).
Let me expand on this, because there's a seemingly obvious response that Coleman gives a little later in the lecture, using David Albert's "definiteness" operator, showing that, just as the linear superposition of all the straight-line tracks is an eigenstate of the "linearity" operator L, the linear superposition of all the states of the observer, in each one of which they observe a straight line track (or whatever other set of possible definite outcomes we are looking at in a particular experiment) is an eigenstate of the "definiteness" operator D. (I first saw this argument in one of David Albert's books many years ago.)PeterDonis said:I don't think this argument does what it's claimed to do: it doesn't explain why we see a single straight line track in a cloud chamber. In fact it implies that we shouldn't!
Yeah, after my reply to Demystfier #48, I also became unsure.PeterDonis said:In other words, I don't think this argument does what it's claimed to do:
If his argument should be too weak to explain why we see a single straight line track, then I feel it should also be too weak to imply the opposite.PeterDonis said:it doesn't explain why we see a single straight line track in a cloud chamber. In fact it implies that we shouldn't!
And to take this further: if we assume that states of the observer in which they observe a single straight-line track in a cloud chamber are eigenstates of W, it's easy to show that a linear superposition of all those states is not an eigenstate of W. Why? Because the states all have different eigenvalues.PeterDonis said:W is the operator that needs to be analyzed to explain why we observe definite outcomes. But Coleman never even talks about it.
I didn't say it was too weak to explain why we see a single straight line track. I said it (quite strongly) leads to the opposite prediction, that we should not see a single straight line track. And I've now amplified that further with a few follow-up posts.gentzen said:If his argument should be too weak to explain why we see a single straight line track
Exactly!PeterDonis said:The problem is that, when we look at the outcome of an experiment, we don't just get a feeling that there is a definite outcome--we observe which outcome it is.
Good, but then I simply disagree with you on that point.PeterDonis said:I didn't say it was too weak to explain why we see a single straight line track. I said it (quite strongly) leads to the opposite prediction, that we should not see a single straight line track. And I've now amplified that further with a few follow-up posts.
In other words, you're using a different interpretation from Coleman. That means we should be discussing your viewpoint in a separate thread. In this one we're using the interpretation Coleman is using, and we should be addressing his arguments using that interpretation. The fact that a different interpretation might make different arguments is off topic for this thread. Indeed, if you are using a different interpretation, you should be just fine with saying that Coleman's arguments, using Coleman's interpretation, are incorrect--after all, you don't agree with his interpretation anyway!gentzen said:I simply disagree with you on that point.
I mean, as a proponent of the consistent histories interpretation
Fine, but I claim that this space, in the given setup, is effectively 2-dimensional as well.gentzen said:Not for Coleman. For him, the relevant Hilbert space is that of the dots.
That's the crucial thing. Why do you think that for Coleman there are states ##|none\rangle## and ##|both\rangle##? In addition, should we also include states like ##|3\; dots\rangle##?gentzen said:For Coleman, there are states ##|none\rangle## and ##|both\rangle##. And Coleman does not mean a superposition such as ##|up\rangle+|down\rangle## by this.
No, I tried to guess what you might have in mind when you claimed: "I said it (quite strongly) leads to the opposite prediction, that we should not see a single straight line track."PeterDonis said:In other words, you're using a different interpretation from Coleman.
Because he cares about the state of the cloud chamber, i.e. the state of the measurement apparatus. And if the possible dots constitue the measurement apparatus, then both "no dots" and "two dots" are possible results, and both have corresponding states.Demystifier said:That's the crucial thing. Why do you think that for Coleman there are states ##|none\rangle## and ##|both\rangle##?
Your post #80 sure looked to me like you were using the consistent histories interpretation to analyze it.gentzen said:I didn't use any interpretation of quantum mechanics when I tried to follow Coleman's argument.
But these states have zero probability of appearing, given that exactly one particle interacts with the apparatus. The Hilbert space spanned by such states is orthogonal to anything of physical relevance in the given setup. Otherwise, we should also include states like ##|3\; dots\rangle##, or even ##|one\; star\rangle## corresponding to the result of measurement in which a star-shaped outcome appears, rather than a dot-shaped one.gentzen said:Because he cares about the state of the cloud chamber, i.e. the state of the measurement apparatus. And if the possible dots constitue the measurement apparatus, then both "no dots" and "two dots" are possible results, and both have corresponding states.
If I need to spell it out, sure. It's simple:gentzen said:Coleman's argument certainly does not convince me that I "should not see a single straight line track"!
The observation is just the eigenvalue and its associated eigenspace. Even so there is a state after measurement, I don't always learn that state during measurement. If there were only one eigenvector corresponding to the measured eigenvalue, then I would learn the state after measurement. But this is not the case here.PeterDonis said:we should observe a linear superposition of all of them, since that's the state after the measurement,
That is the part where I don't agree with you. For me, only the eigenspace represents what I observed. The concrete state after measurement within that eigenspace remains unknown to me.PeterDonis said:and the state after the measurement is supposed to represent what we observed.
Well, the associated eigenspace of L with eigenvalue +1 is the entire space of possible linear superpositions of straight-line tracks. It certainly is not just one single straight-line track.gentzen said:The observation is just the eigenvalue and its associated eigenspace.
Even if you know that the initial prepared state was a particular state within that eigenspace? AFAIK standard QM says that if you know the prepared state is one particular eigenstate within an eigenspace, measuring that operator leaves the state in that initial prepared state.gentzen said:For me, only the eigenspace represents what I observed. The concrete state after measurement within that eigenspace remains unknown to me.
Turns out L should be consistent with those more mundane measurement operators. They should be a simple refinement of L. (I have no opinion about D, because it feels complicated and hard to define to me.)gentzen said:I mean, as a proponent of the consistent histories interpretation, I wonder whether those strange measurement operators L and D will not be inconsistent with more mundane measurement operators just observing whether some specific classical configuration occurred.