Is quantum theory a microscopic theory?

In summary, the conversation discusses whether quantum theory is a theory of the microscopic world or not. While some interpretations of quantum theory explicitly deal with microscopic objects, the minimal instrumental view refrains from doing so and only focuses on predicting the probabilities of macroscopic measurement outcomes. The conversation also touches on the idea of microscopic objects being defined through their detection, which would make them not truly microscopic. Ultimately, the conversation suggests that quantum theory can only be considered a theory of the micro world if one adopts an ontic interpretation.
  • #36
QT also applies to macroscopic systems as its very successful use in condensed-matter physics shows.
 
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  • #37
I think @atyy is referring to how in Copenhagen presentations (Peres, Landau & Lifshitz, Weinberg 2nd Edition) quantum theory is formulated in terms of observables witnessed by a device that's treated classically. In technical language the classical device constitutes the Boolean frame with respect to which outcomes occur.

Of course one can then treat the device itself quantum mechanically, but this is from the perspective of the presence of a separate larger device that is treated classically which is capable of measuring the first. So everything can be described quantum mechanically, but not everything at once.

It's not as such a micro/macro division or that QM does not apply above a certain scale, just something must lie outside the theory to constitute the outcomes. The above mentioned textbooks discuss this.
 
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  • #38
DarMM said:
I think @atyy is referring to how in Copenhagen presentations (Peres, Landau & Lifshitz, Weinberg 2nd Edition) quantum theory is formulated in terms of observables witnessed by a device that's treated classically. In technical language the classical device constitutes the Boolean frame with respect to which outcomes occur.

Of course one can then treat the device itself quantum mechanically, but this is from the perspective of the presence of a separate larger device that is treated classically which is capable of measuring the first. So everything can be described quantum mechanically, but not everything at once.

It's not as such a micro/macro division or that QM does not apply above a certain scale, just something must lie outside the theory to constitute the outcomes. The above mentioned textbooks discuss this.
Yes, but what is the theorem that states that it must be so? Take for example classical physics (non quantum), you can have a system consisting of a large number of particles obeying Newton's laws that exhibits new emergent behavior. The system may have constant temperature, pressure, and volume although the individual particles are in constant motion, and some of the emergent properties don't even make sense for the individual building blocks. So, what in QT forbits an emergent classical behavior? Why is it impossible for the chair, I am sitting on, to be made of many QM particles obeying QM's laws and having classical properties, that follow from the QM's laws?
 
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  • #39
I'd rather say, it's because of QT that we have a stable chair to sit on!
 
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  • #40
martinbn said:
Yes, but what is the theorem that states that it must be so? Take for example classical physics (non quantum), you can have a system consisting of a large number of particles obeying Newton's laws that exhibits new emergent behavior. The system may have constant temperature, pressure, and volume although the individual particles are in constant motion, and some of the emergent properties don't even make sense for the individual building blocks. So, what in QT forbits an emergent classical behavior? Why is it impossible for the chair, I am sitting on, to be made of many QM particles obeying QM's laws and having classical properties, that follow from the QM's laws?
As I said above there's nothing preventing you from treating the device quantum mechanically, thus it's not a problem with obtaining emergent classical behavior. It's a separate problem. It's that when you do model the device with QM you invoke a second device that is treated classically. You could treat this device with qm, but you invoke a third device and so on. This is sometimes known as the Von Neumann chain.

The presence of something not modeled with QM that selects a particular Boolean frame is always assumed in typical Copenhagen presentations of the theory.

This is not the case in classical theories, where the theory is not written with reference to a system lying outside the theory.
 
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  • #41
DarMM said:
As I said above there's nothing preventing you from treating the device quantum mechanically, thus it's not a problem with obtaining emergent classical behavior. It's a separate problem. It's that when you do model the device with QM you invoke a second device that is treated classically. You could treat this device with qm, but you invoke a third device and so on. This is sometimes known as the Von Neumann chain.

The presence of something not modeled with QM that selects a particular Boolean frame is always assumed in typical Copenhagen presentations of the theory.

This is not the case in classical theories, where the theory is not written with reference to a system lying outside the theory.
Why do I need a second device? I have a QM system which is in a state (evolves to a state) that is classical in a certain sense, and I know that because it is a consequence of the theory, I don't need a second devise. Just like the classical physics case. If I have gas in a box, I can talk about its temperature without the need of a thermometer.
 
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  • #42
It's due to the fact that QM won't give the actual resultant state of the device. The device will end up with terms for each outcome rather than the one it actually displays. Thus in the Copenhagen reading it predicts the chances for a second device to observe the first in its various pointer states.

This is quite an old issue. It's in Von Neumann's book and the ones I mentioned above.
 
  • #43
DarMM said:
It's due to the fact that QM won't give the actual resultant state of the device. The device will end up with terms for each outcome rather than the one it actually displays. Thus in the Copenhagen reading it predicts the chances for a second device to observe the first in its various pointer states.

This is quite an old issue. It's in Von Neumann's book and the ones I mentioned above.
That's not the issue. I am not talking about any measurements. @atyy said that QM doesn't allow (at least it seems so) to say that a classically behaving object is made out of quantum mechanical particles. My question is how so?
 
  • #44
martinbn said:
That's not the issue. I am not talking about any measurements. @atyy said that QM doesn't allow (at least it seems so) to say that a classically behaving object is made out of quantum mechanical particles. My question is how so?
I'm only assuming, so perhaps I'm wrong, my guess is that he was referring to the Von Neumann chain where one always has some system present that's not modeled as being made of quantum particles.
 
  • #45
martinbn said:
That's not the issue. I am not talking about any measurements
Another aspect of the problem is that in QM you're always talking about measurements with respect to some device modeled classically. There have been attempts to remove this and have QM not require a classical device. Such as decoherent histories. However although they achieve much they don't manage this. Weinberg in the 2nd edition of his text has a nice exposition on this.

Of course anything may be modeled quantum mechanically, but you always invoke a classical device.

This is confined to Copenhagen style views.
 
  • #46
If quantum theory is nothing but a set or rules to compute the probabilities of macroscopic measurement outcomes, then what is microscopic about it?
I surely wouldn't say quantum theory "is nothing but a set of rules". Perhaps you meant "quantum mechanics"? Quantum mechanics is pretty well understood but there are a number of different "theories" about what is behind the mechanics.

In any case, the only experiments we can do are pretty much "macroscopic" because we are macroscopic. Quantum theory is a theory about how microscopic events can affect macroscopic observations. In that sense it is "microscopic".
 
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  • #47
DarMM said:
Another aspect of the problem is that in QM you're always talking about measurements with respect to some device modeled classically. There have been attempts to remove this and have QM not require a classical device. Such as decoherent histories. However although they achieve much they don't manage this. Weinberg in the 2nd edition of his text has a nice exposition on this.

Of course anything may be modeled quantum mechanically, but you always invoke a classical device.

This is confined to Copenhagen style views.
I never understood why that is a problem. Why should a theory not use classical objects in its formulation?
 
  • #48
martinbn said:
I never understood why that is a problem. Why should a theory not use classical objects in its formulation?
Practically it's no issue.

It's more that some think a theory should be able to describe the world without requiring objects outside the theory acting as "witnesses" to define events.

For example just describing an electron on its own, not needing to include a measuring device.
 
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  • #49
The Bill said:
Do you consider atoms, molecules, atomic bonds, etc. to be microscopic?

If the answer to both of those is yes, then quantum theory has told us about features of the microscopic world.
I do not say that QM does not say anything about the micro world. I say that the minimal instrumental form of QM does not say anything about the micro world.
 
  • #50
Mentz114 said:
Daft question. Quantum theory is the most successful theory known to mankind. No prediction has ever been contradicted and mathematical precision is ##O(10^{-12})##
I do not question the success of quantum theory. I question that quantum theory is about the microscopic world. Or more precisely, I question that one particular view of QM is about the microscopic world.
 
  • #51
TeethWhitener said:
Your answer seems to imply that only detections are macroscopic (macroscopic = detection).
No, I imply that all detections are macroscopic. But the converse is not true, some macro objects may not be detections.
 
  • #52
vanhees71 said:
There is no classical/quantum cut to be well defined within quantum theory.
True, but there is a measurement/no-measurement cut within the minimal instrumental view of QM.
 
  • #53
vanhees71 said:
There's only a measurement problem, if you insist on an ontic interpretation. The very success of QT in describing all known observables disproves the existence of any "measurement problem". QT precisely describes all results of measurement in the real world, and thus there's no measurement problem in any scientific sense.
1. As long as there is no measurement problem in QT, there is a problem of whether QT is about the microscopic world.
2. As long as there is no problem of whether QT is about the microscopic world, there is a measurement problem in QT.
3. As long as there is neither measurement problem in QT nor a problem of whether QT is about the microscopic world, there is a problem with logical consistency of QT.
 
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  • #54
martinbn said:
Why should a theory not use classical objects in its formulation?
A theory can use classical objects in its formulation, but not if that theory (like QM) claims that it can derive the classical objects. Using classical objects in formulation of a theory more fundamental than classical physics would be like using mathematical analysis in ZFC axioms of set theory.
 
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  • #55
Demystifier said:
I say that the minimal instrumental form of QM does not say anything about the micro world.

That's indeed the point. Cord Friebe, Holger Lyre, Manfred Stöckler, Meinard Kuhlmann, Oliver Passon and Paul M. Näger in “The Philosophy of Quantum Physics”:

“If one tries to proceed systematically, then it is expedient to begin with an interpretation upon which everyone can agree, that is with an instrumentalist minimal interpretation. In such an interpretation, Hermitian operators represent macroscopic measurement apparatus, and their eigenvalues indicate the measurement outcomes which can be observed, while inner products give the probabilities of obtaining particular measured values. With such a formulation, quantum mechanics remains stuck in the macroscopic world and avoids any sort of ontological statement about the (microscopic) quantum-physical system itself.”
 
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  • #56
Lord Jestocost said:
That's indeed the point. Cord Friebe, Holger Lyre, Manfred Stöckler, Meinard Kuhlmann, Oliver Passon and Paul M. Näger in “The Philosophy of Quantum Physics”:

“If one tries to proceed systematically, then it is expedient to begin with an interpretation upon which everyone can agree, that is with an instrumentalist minimal interpretation. In such an interpretation, Hermitian operators represent macroscopic measurement apparatus, and their eigenvalues indicate the measurement outcomes which can be observed, while inner products give the probabilities of obtaining particular measured values. With such a formulation, quantum mechanics remains stuck in the macroscopic world and avoids any sort of ontological statement about the (microscopic) quantum-physical system itself.”
Yes, that's exactly what I say, nice to see that I am not alone. :smile:
 
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  • #57
So what?
 
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  • #58
Demystifier said:
I do not question the success of quantum theory. I question that quantum theory is about the microscopic world. Or more precisely, I question that one particular view of QM is about the microscopic world.
The core formalism of QT allows us to make predictions about microscopic things by observing macroscopic outcomes of experiments. For instance the behaviour of atoms interacting with the EM field in cavities.
I think I miss the point of your question. It is true that we can only predict probabilities, and that imposes a limit what we can infer.
 
  • #59
Mentz114 said:
to make predictions about microscopic things by observing macroscopic outcomes of experiments.

The “microscopic things” are merely mental concepts which one uses to “describe” the behavior of measuring instruments in a given experimental context.
 
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  • #60
Lord Jestocost said:
The “microscopic things” are merely mental concepts which one uses to “describe” the behavior of measuring instruments in a given experimental context.
No. Atoms really do exist ! The only mental concept involved is probability which does not share the same kind of existence.
 
  • #61
But we reveal the "existence" of microscopic atoms via macroscopic devices...
Mentz114 said:
No. Atoms really do exist !
 
  • #62
Schwann said:
But we reveal the "existence" of atoms via macroscopic devices...
If that is the case then QT does tell us something about the microscopic world and the philosophical doubts are proved meaningless.
 
  • #63
Mentz114 said:
No. Atoms really do exist !

The question is: Does an atom “exist” on its own in the full, common-sense notion of the word so that it can be given a description in its own right or is it only a phenomenon in case it is an observed/registered phenomenon?
 
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  • #64
vanhees71 said:
So what?

Maybe there is some theory that is.
Though the question this thread poses... has me scratching my head... is there some Godel-like proof that there can never be? I mean any theory we could point to is going to be an invention starting in a classical experience (ours) of the frustratingly in-naccessible (in the classical sense) quantum realm so... what hope is there?

Is that the point of the OP?
 
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  • #65
Lord Jestocost said:
The question is: Does an atom “exist” on its own in the full, common-sense notion of the word so that it can be given a description in its own right or is it only a phenomenon in case it is an observed/registered phenomenon?
I would apply that definition of existence to anything that is claimed to exist. A Rydberg atom in a microwave resonant cavity is a vey tiny thing in a relatively huge volume.. We cannot hope to affirm its existence as we might do for a baseball. But experiment shows that there is something there which is interacting with the EM field - as predicted. So that atom existed. That atom made headlines in the 1960's !
 
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  • #66
This discussion reminds me of the day, many years ago, when my physics teacher (a Nobel prize nominee) handed back an exam paper on the Dirac equation and sternly said, "Fred, the neutron, she's not a little potato!"
 
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  • #67
Well QM in the typical Copenhagen reading is a theory of the statistics of impressions microscopic systems leave in macroscopic objects. So it does concern the microscopic, but it's not a representational theory telling you what they are like in and of themselves.
 
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  • #68
Demystifier said:
A theory can use classical objects in its formulation, but not if that theory (like QM) claims that it can derive the classical objects. Using classical objects in formulation of a theory more fundamental than classical physics would be like using mathematical analysis in ZFC axioms of set theory.
Well, can QM derive that? May be people think too highly of QM. If you admit that it isn't the most fundamental, the last word, then there wouldn't be "problems" that need interpretations to "solve" them.
 
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  • #69
martinbn said:
Well, can QM derive that? May be people think too highly of QM. If you admit that it isn't the most fundamental, the last word, then there wouldn't be "problems" that need interpretations to "solve" them.
The problem to many is that no-go theorems imply QM is the last word unless you're willing to have multiple worlds, retrocausality or nonlocality. A theory which is the last word and leaves in place classical objects outside it is unsatisfying to many.
 
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  • #70
atyy said:
No, since we would like to say the classical measurement apparatus is made of electrons, which are quantum. However, quantum mechanics does not seem to allow us to say that.

Can you push it to the nucleus too. About your "Is the measurement apparatus (classical macroscopic) made of electrons (quantum microscopic)?". Can you also ask ""Is the measurement apparatus (classical macroscopic) made of atomic nuclei (quantum microscopic)?"? (and the answer not necessarily being yes)
 
<h2>1. What is quantum theory?</h2><p>Quantum theory, also known as quantum mechanics, is a branch of physics that describes the behavior of particles at the microscopic level. It is a mathematical framework that explains the strange and counterintuitive behavior of particles such as atoms and subatomic particles.</p><h2>2. How does quantum theory differ from classical physics?</h2><p>Quantum theory differs from classical physics in that it describes the behavior of particles at the microscopic level, while classical physics explains the behavior of larger objects. Quantum theory also introduces the concept of uncertainty and the wave-particle duality, which are not present in classical physics.</p><h2>3. Is quantum theory a complete theory?</h2><p>No, quantum theory is not a complete theory. It is still an active area of research and there are many unanswered questions and mysteries surrounding it. Scientists are constantly working to improve and expand upon quantum theory.</p><h2>4. How does quantum theory relate to the macroscopic world?</h2><p>While quantum theory is primarily used to explain the behavior of particles at the microscopic level, it also has implications for the macroscopic world. Many of the technological advancements we have today, such as transistors and lasers, rely on the principles of quantum theory.</p><h2>5. Can quantum theory be applied to all aspects of science?</h2><p>Quantum theory is a fundamental theory that can be applied to many aspects of science, including chemistry, biology, and even cosmology. However, there are still limitations and areas where it may not fully apply, such as in the study of gravity.</p>

1. What is quantum theory?

Quantum theory, also known as quantum mechanics, is a branch of physics that describes the behavior of particles at the microscopic level. It is a mathematical framework that explains the strange and counterintuitive behavior of particles such as atoms and subatomic particles.

2. How does quantum theory differ from classical physics?

Quantum theory differs from classical physics in that it describes the behavior of particles at the microscopic level, while classical physics explains the behavior of larger objects. Quantum theory also introduces the concept of uncertainty and the wave-particle duality, which are not present in classical physics.

3. Is quantum theory a complete theory?

No, quantum theory is not a complete theory. It is still an active area of research and there are many unanswered questions and mysteries surrounding it. Scientists are constantly working to improve and expand upon quantum theory.

4. How does quantum theory relate to the macroscopic world?

While quantum theory is primarily used to explain the behavior of particles at the microscopic level, it also has implications for the macroscopic world. Many of the technological advancements we have today, such as transistors and lasers, rely on the principles of quantum theory.

5. Can quantum theory be applied to all aspects of science?

Quantum theory is a fundamental theory that can be applied to many aspects of science, including chemistry, biology, and even cosmology. However, there are still limitations and areas where it may not fully apply, such as in the study of gravity.

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