How does the thermal interpretation explain Stern-Gerlach?

In summary, the thermal interpretation views the measurement of a Hermitian quantity as giving an uncertain value approximating the q-expectation, rather than an exact revelation of an eigenvalue. Applied to the Stern-Gerlach experiment, the observed result is seen as an uncertain measurement of the q-expectation of the spin-x operator, which is zero for a beam of spin-z up electrons passing through a Stern-Gerlach device oriented in the x direction. However, this interpretation is inconsistent with the classical prediction of a normal distribution for a quantity with a q-expectation of zero. In the thermal interpretation, the measurement device is always treated as a quantum device, and the beam is represented as a quantum field with a sharp number
  • #71
DarMM said:
Rather it is a bilocal property, that is a nonlocal property that requires measurements at two locations to ascertain. It has a fixed deterministic value.

If there is a fixed deterministic value, it does not mean anything to say it is bilocal, and it would be trivial to describe it this way. A fixed, deterministic bilocal value is of the form "particle A is spin up and particle B is spin down". All you really have here are two separate, local claims, namely: "particle A is spin up"; "particle B is spin down." Assigning bilocal HVs like this is isomorphic to assigning local HVs and cannot by themselves violate Bell ineqs.
 
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  • #72
charters said:
A fixed, deterministic bilocal value is of the form "particle A is spin up and particle B is spin down".
There are more general deterministic bilocal properties, those of the kind ''The bilocal variable ##C(x,y)## has a given value at a pair of spacetime positions ##x,y##''.
 
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  • #73
A. Neumaier said:
In a classical Laplacian universe, a Laplacian detector of finite size perfectly knowing its own state can never get an arbitrarily accurate estimate of a single particle state external to it. Thus a classical Laplacian universe would be superdeterministic.

Why does that make it superdeterministic? The reason superdeterminism is relevant to interpretations of quantum mechanics, as I said, is because superdeterminism is a loophole in Bell's argument against local hidden variables theories. In an attempt to reproduce the statistics of spin-1/2 EPR, you would have five "players":
  1. Alice, who chooses a detector orientation ##\overrightarrow{\alpha}##
  2. Bob, who chooses a detector orientation ##\overrightarrow{\beta}##
  3. Charlie, who chooses a value for ##\lambda## according to some probability distribution ##P(\lambda)##
  4. Alice's detector, that computes a result ##A(\overrightarrow{\alpha}, \lambda) = \pm 1## based on ##\overrightarrow{\alpha}## and ##\lambda##
  5. Bob's detector, that picks a result ##B(\overrightarrow{\beta}, \lambda) = \pm 1## based on ##\overrightarrow{\beta}## and ##\lambda##
Bell shows that there is no probability distribution ##P(\lambda)## that can reproduce the correlations predicted by quantum mechanics. However, there are a number of loopholes in the argument:

  1. if Bob's detector is allowed to depend on ##\overrightarrow{\alpha}##, or if Alice's detector is allowed to depend on ##\overrightarrow{\beta}## (nonlocality) then there is no problem in reproducing the predictions of quantum mechanics.
  2. If Charlie's choice of ##\lambda## is allowed to depend on ##\overrightarrow{\alpha}## and ##\overrightarrow{\beta}## (superdeterminism), then there is no problem in reproducing the predictions of quantum mechanics.
Alice being a deterministic machine doesn't make her choice predictable, because as I argued earlier, Alice can consult the whole rest of the universe in order to make her choice. Simple determinism would allow us to predict Alice's choice based on her state plus the inputs she receives from the rest of the universe. Superdeterminism would require that not only Alice but the whole rest of the universe be known and predictable.
 
  • #74
stevendaryl said:
Why does that make it superdeterministic?
It was, in my tentative understanding of DarMM's definition of superdeterminism. In the mean time, he clarified his definition, and in my resulting understanding, my old comment makes no longer sense.
stevendaryl said:
superdeterminism is a loophole in Bell's argument against local hidden variables theories.
Since the thermal interpretation has multilocal hidden variables, Bell's argument doesn't apply anyway.
 
  • #75
A. Neumaier said:
Since the thermal interpretation has multilocal hidden variables, Bell's argument doesn't apply anyway.

How does "multilocal hidden variables" explain the EPR results?
 
  • #76
stevendaryl said:
How do "multilocal hidden variables" explain the EPR results?
They don't explain them by itself, they are just outside the scope of Bell's arguments since his assumptions are incompatible with multilocal hidden variables.

The explanation of the nonclassical long-distance correlations is the standard quantum dynamics, which is assumed exact in the thermal interpretation and predicts the standard correlations. These are bilocal beables, approximately measurable (by the weak law of large numbers as any q-expectation; see Section 3 of Part II of my series of papers) through averaging over many independent realizations of discrete tests. The discrete response is explained by environment-induced randomness and environment-induced dissipation, as discussed in Subsections 4.3 and 5.1 of Part III.

The thermal interpretation does not give an explanation, though, of how Nature is able to figure out how to behave according to the quantum laws. It just follows them.
 
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  • #77
charters said:
If there is a fixed deterministic value, it does not mean anything to say it is bilocal
I think a deterministic variable can be bilocal is a well defined concept, I don't understand how it is meaningless. It might be wrong, but to have no meaning seems unlikely to me.

charters said:
A fixed, deterministic bilocal value is of the form "particle A is spin up and particle B is spin down". All you really have here are two separate, local claims, namely: "particle A is spin up"; "particle B is spin down." Assigning bilocal HVs like this is isomorphic to assigning local HVs and cannot by themselves violate Bell ineqs.
That's not what is happening in the Thermal Interpretation, the fixed deterministic value is not "A is up and B is down" or anything like that. First before I explain further, have you read @A. Neumaier 's papers in detail? In order to know what level of detail to go into.
 
  • #78
DarMM said:
That's not what is happening in the Thermal Interpretation, the fixed deterministic value is not "A is up and B is down" or anything like that.
Then what is it? Perhaps something like ##(A,B)=(up,down)##?
 
  • #80
Demystifier said:
Then what is it? Perhaps something like ##(A,B)=(up,down)##?
One has the quantity ##\langle AB\rangle##, not understood in the typical probabilistic manner as a correlation between ##A## and ##B## but as a quantity in and of itself. This can take a continuous range of values.

There are then the local variables ##\langle A\rangle## and ##\langle B\rangle##. The quantum mechanical state does imply that there is a constraint between their values, but fundamentally they are separate quantities.

Local observations of ##\langle A\rangle## and ##\langle B\rangle## appear discrete due to how the device's slow modes evolve.

However repeated observation of ##\langle A\rangle## and ##\langle B\rangle## allows one to obtain statistical estimates on their values.

Then by comparing the joint statistics of ##\langle A\rangle## and ##\langle B\rangle## you can also obtain an estimate of the value of ##\langle AB\rangle##.
 
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  • #81
DarMM said:
Then by comparing the statistics of ##\langle A\rangle## and ##\langle B\rangle## you can also obtain an estimate of the value of ##\langle AB\rangle##.
by comparing their joint statistics
 
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  • #82
DarMM said:
That's not what is happening in the Thermal Interpretation, the fixed deterministic value is not "A is up and B is down" or anything like that. First before I explain further, have you read @A. Neumaier 's papers in detail? In order to know what level of detail to go into.

I have read the papers, but I think what will be more helpful is for you to simply state a fixed, deterministic HV that is a counterexample. This disagreement is not really about the TI, it is a much more general question of what it means for anything to be a hidden variable.

My argument is very simple: in a deterministic hidden variables interpretation, you must assign hidden variable which uniquely predicts the outcome of each local measurement. Otherwise, local measurements cannot be deterministic. If local measurements are not deterministic, the interpretation is not deterministic. The Bell's theorem non-locality only enters as a means of correcting the HVs when necessary, reacting to other local measurements performed elsewhere. This will be a de facto pilot wave.

If, as you say, "the fixed deterministic value is not "A is up and B is down" or anything like that" then I do not see what it can even mean to call these values fixed or deterministic.

Arnold has suggested:

A. Neumaier said:
There are more general deterministic bilocal properties, those of the kind ''The bilocal variable ##C(x,y)## has a given value at a pair of spacetime positions ##x,y##''.

But I can just turn this around into: "the value at spacetime point x is C(x)" and "the value at spacetime point y is C(y)". As long as C(x,y) maps to a pair of unique values (not a statistical mixture at each local site), this is clearly isomorphic to the above. If C(x,y) maps to statistical mixtures at each local site, this bilocal variable is not a deterministic HV for local measurements.

Dar, you said:

DarMM said:
However repeated observation of ⟨A⟩⟨A⟩\langle A\rangle and ⟨B⟩⟨B⟩\langle B\rangle allows one to obtain statistical estimates on their values.

Then by comparing the joint statistics of ⟨A⟩⟨A⟩\langle A\rangle and ⟨B⟩⟨B⟩\langle B\rangle you can also obtain an estimate of the value of ⟨AB⟩⟨AB⟩\langle AB\rangle.

If each individual observation of ⟨A⟩ and ⟨B⟩ reveals a preexisting hidden variable of ⟨A⟩ or ⟨B⟩, the joint stats will not violate Bell ineqs without assuming something more (pilot wave, superdeterminism).

If there are no preexisting hidden variables for ⟨A⟩ and ⟨B⟩ individually, local measurements are not deterministic, and this is not a deterministic HV interpretation at all.
 
  • #83
charters said:
As long as C(x,y) maps to a pair of unique values

Which it might not; that's exactly the point. Not every function of two variables can be decomposed into two functions, each of one variable.
 
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  • #84
PeterDonis said:
Which it might not; that's exactly the point. Not every function of two variables can be decomposed into two functions, each of one variable.

I agree. But if it doesn't do this, it is not going to make deterministic predictions for local measurements of an individual subsystem.
 
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  • #85
DarMM said:
I think a deterministic variable can be bilocal is a well defined concept, I don't understand how it is meaningless. It might be wrong, but to have no meaning seems unlikely to me.
I have already given such example in a post two years ago, which is nothing but a generalization of the concept I gave in this post, the lines connecting two points can represent energy(or momentum times speed of light).
 
  • #86
charters said:
I have read the papers, but I think what will be more helpful is for you to simply state a fixed, deterministic HV that is a counterexample. This disagreement is not really about the TI, it is a much more general question of what it means for anything to be a hidden variable.

My argument is very simple: in a deterministic hidden variables interpretation, you must assign hidden variable which uniquely predicts the outcome of each local measurement. Otherwise, local measurements cannot be deterministic. If local measurements are not deterministic, the interpretation is not deterministic. The Bell's theorem non-locality only enters as a means of correcting the HVs when necessary, reacting to other local measurements performed elsewhere. This will be a de facto pilot wave.

If, as you say, "the fixed deterministic value is not "A is up and B is down" or anything like that" then I do not see what it can even mean to call these values fixed or deterministic.

Arnold has suggested:
But I can just turn this around into: "the value at spacetime point x is C(x)" and "the value at spacetime point y is C(y)". As long as C(x,y) maps to a pair of unique values (not a statistical mixture at each local site), this is clearly isomorphic to the above. If C(x,y) maps to statistical mixtures at each local site, this bilocal variable is not a deterministic HV for local measurements.

Dar, you said:
If each individual observation of ⟨A⟩ and ⟨B⟩ reveals a preexisting hidden variable of ⟨A⟩ or ⟨B⟩, the joint stats will not violate Bell ineqs without assuming something more (pilot wave, superdeterminism).

If there are no preexisting hidden variables for ⟨A⟩ and ⟨B⟩ individually, local measurements are not deterministic, and this is not a deterministic HV interpretation at all.
There are local pointer variables a(x) and b(y) but their deterministic dynamics depends on bilocal and mulilocal variables.
 
  • #87
A. Neumaier said:
There are local pointer variables a(x) and b(y) but their deterministic dynamics depends on bilocal and mulilocal variables.

Ok this I can agree is a workable and well understood solution to Bell's theorem. Basically, instead of saying a "pilot wave" is steering the deterministic time evolution of the local pointer variables, the TI says it is "multilocal variables" doing so.
 
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  • #88
charters said:
Ok this I can agree is a workable and well understood solution to Bell's theorem. Basically, instead of saying a "pilot wave" is steering the deterministic time evolution of the local pointer variables, the TI says it is "multilocal variables" doing so.
The nonlocal dynamics is the Ehrenfest dynamics introduced in Section 2 of my Part II paper.
 
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  • #89
A. Neumaier said:
There are local pointer variables a(x) and b(y) but their deterministic dynamics depends on bilocal and mulilocal variables.
I don't think that their dynamics depends on bilocal and multilocal variables. Their dynamics is given by equations of the form
$$\langle a(x,t)\rangle={\rm Tr}\rho(t)a(x)$$
which depends only on the state of the Universe ##\rho(t)##.
 
  • #90
$$\def\<{\langle} \def\>{\rangle}$$
Demystifier said:
I don't think that their dynamics depends on bilocal and multilocal variables. Their dynamics is given by equations of the form
$$\langle a(x,t)\rangle={\rm Tr}~\rho(t)a(x)$$
which depends only on the state of the Universe ##\rho(t)##.
Only in the noncovariant Schrödinger picture, where the essence of the thermal interpretation is hidden: Your ##a(x)## is a space-dependent operator depending on spatial coordinates ##x##. On the other hand,
A. Neumaier said:
The nonlocal dynamics is the Ehrenfest dynamics introduced in Section 2 of my Part II paper.
I was using covariant beables ##a(x) =\langle A(x)\rangle={\rm Tr}~\rho A(x)## in the covariant Heisenberg picture dependent on a vector of spacetime coordinates ##x##, with a fixed state of the universe. Their dynamics is given by the covariant Ehrenfest equation (Section 4.2 of Part II)
##\frac{d}{dx_\nu} \<A\>_x=\<p_\nu~\angle~ A(x)\>##, specialized to ##t=x_0/c##, giving
$$\frac{d}{dt} \<A\>_x=\<H~\angle~ A(x)\>,$$
where ##H=cp_0## is the (frame-dependent) Hamiltonian of the quantum field theory of the universe and ##A ~\angle~ B:=\frac{i}{\hbar}[A,B]##; see Section 2 of Part II.

Since ##H## is a sum of integrals over multilocal operators, the right hand side is a sum of integrals over multilocal q-expectations.
 
  • #91
A. Neumaier said:
##H## is a sum of integrals over multilocal operators
Can you better explain what do you mean by that? (Pinpoiting to the right part of your paper would be OK.)
 
  • #92
Demystifier said:
Can you better explain what do you mean by that? (Pinpointing to the right part of your paper would be OK.)
In my paper I didn't discuss the detailed form of the Hamiltonian of the universe. It depends on stuff yet to be discovered about how to represent quantum gravity. But the general form of the Hamiltonian is already visible from simpler quantum field theories such as QED, where it is derived as usual from the action, and later modified through renormalization.

Already a free Hamiltonian contains a term with a spatial integral over quadratic expressions, and interactions plus renormalization at all orders add terms of all higher degrees, which become multilocal when inserted into the Ehrenfest dynamics. (Search for Hamiltonian in this Wikipedia article to find the explicit unrenormalized expression for scalar field theory; the integration variable runs over points distinct from the ##x## in the Ehrenfest equation.)
 
  • #93
Hi all,

sorry if I post in a relatively old thread.

charters said:
Ok this I can agree is a workable and well understood solution to Bell's theorem. Basically, instead of saying a "pilot wave" is steering the deterministic time evolution of the local pointer variables, the TI says it is "multilocal variables" doing so.

Personally, I do not understand how can one avoid a 'non-locality' of the kind of the pilot-wave theory if multi-local properties dependent on more than one space-like separated space-time regions are accepted. Are there any references on this?
Also, is the thermal interpretation the only one that uses this possible solution to Bell's theorem?
 
  • #94
indefinite_123 said:
I do not understand how can one avoid a 'non-locality' of the kind of the pilot-wave theory if multi-local properties dependent on more than one space-like separated space-time regions are accepted. Are there any references on this?
I discuss nonlocality in Part II of my preprints, Section 4.5, mentioned in post #1 of the main thread on the TI (linked to in post #2 of the present thread) .

For a more polished account of bilocal quantities and nonlocality see my recent book also mentioned there.
 
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  • #95
A. Neumaier said:
I discuss nonlocality in Part II of my preprints, Section 4.5, mentioned in post #1 of the main thread on the TI (linked to in post #2 of the present thread) .

For a more polished account of bilocal quantities and nonlocality see my recent book also mentioned there.
Thank you very much!
 
<h2>1. How does the thermal interpretation explain the Stern-Gerlach experiment?</h2><p>The thermal interpretation explains the Stern-Gerlach experiment by considering the particles passing through the magnetic field as having a thermal distribution of velocities. This means that the particles have a range of velocities and orientations, and the magnetic field causes them to separate into different paths depending on their velocities and orientations.</p><h2>2. What is the role of temperature in the thermal interpretation of the Stern-Gerlach experiment?</h2><p>Temperature is a key factor in the thermal interpretation of the Stern-Gerlach experiment. It determines the range of velocities and orientations of the particles passing through the magnetic field. Higher temperatures result in a wider range of velocities and orientations, leading to a broader separation of the particles into different paths.</p><h2>3. How does the thermal interpretation explain the deflection of particles in the Stern-Gerlach experiment?</h2><p>The thermal interpretation explains the deflection of particles in the Stern-Gerlach experiment by considering the magnetic field as exerting a force on the particles. This force causes the particles to change direction and follow a curved path, depending on their velocities and orientations. The thermal distribution of velocities and orientations of the particles results in a spread of deflections, leading to the observed separation into different paths.</p><h2>4. Does the thermal interpretation conflict with other interpretations of the Stern-Gerlach experiment?</h2><p>The thermal interpretation does not necessarily conflict with other interpretations of the Stern-Gerlach experiment, such as the quantum mechanical interpretation. It is simply a different way of understanding and explaining the observed phenomenon. The thermal interpretation takes into account the thermal properties of particles, while other interpretations may focus on the quantum mechanical properties of particles.</p><h2>5. How does the thermal interpretation relate to classical physics?</h2><p>The thermal interpretation is based on classical physics principles, such as the concept of thermal motion and the behavior of particles in a magnetic field. It does not involve quantum mechanics, making it a more classical approach to understanding the Stern-Gerlach experiment. However, it is important to note that the thermal interpretation does not fully explain all aspects of the experiment and should be considered alongside other interpretations, including those based on quantum mechanics.</p>

1. How does the thermal interpretation explain the Stern-Gerlach experiment?

The thermal interpretation explains the Stern-Gerlach experiment by considering the particles passing through the magnetic field as having a thermal distribution of velocities. This means that the particles have a range of velocities and orientations, and the magnetic field causes them to separate into different paths depending on their velocities and orientations.

2. What is the role of temperature in the thermal interpretation of the Stern-Gerlach experiment?

Temperature is a key factor in the thermal interpretation of the Stern-Gerlach experiment. It determines the range of velocities and orientations of the particles passing through the magnetic field. Higher temperatures result in a wider range of velocities and orientations, leading to a broader separation of the particles into different paths.

3. How does the thermal interpretation explain the deflection of particles in the Stern-Gerlach experiment?

The thermal interpretation explains the deflection of particles in the Stern-Gerlach experiment by considering the magnetic field as exerting a force on the particles. This force causes the particles to change direction and follow a curved path, depending on their velocities and orientations. The thermal distribution of velocities and orientations of the particles results in a spread of deflections, leading to the observed separation into different paths.

4. Does the thermal interpretation conflict with other interpretations of the Stern-Gerlach experiment?

The thermal interpretation does not necessarily conflict with other interpretations of the Stern-Gerlach experiment, such as the quantum mechanical interpretation. It is simply a different way of understanding and explaining the observed phenomenon. The thermal interpretation takes into account the thermal properties of particles, while other interpretations may focus on the quantum mechanical properties of particles.

5. How does the thermal interpretation relate to classical physics?

The thermal interpretation is based on classical physics principles, such as the concept of thermal motion and the behavior of particles in a magnetic field. It does not involve quantum mechanics, making it a more classical approach to understanding the Stern-Gerlach experiment. However, it is important to note that the thermal interpretation does not fully explain all aspects of the experiment and should be considered alongside other interpretations, including those based on quantum mechanics.

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