Is Entanglement Properly Defined in Bohr's Idea of Complementarity?

  • I
  • Thread starter bhobba
  • Start date
  • Tags
    Bohr
In summary, Bohr thought that the quantum postulate implied that any observation of atomic phenomena would involve an interaction with the agency of observation not to be neglected. This situation has far-reaching consequences, including the definition of the state of a physical system, as ordinarily understood, losing its immediate sense and causality in the ordinary sense of the word becoming complementary but exclusive.
  • #36
EPR said:
So the list of assumptions is almost endless and this open-ended list took us where we currently are.

Debatable would be a better description here. But if you want to discuss any of the things mentioned please start a new thread. But be careful, many of those are really questions in philosophy, not science. And of course we do not discuss philosophy here.

EPR said:
What happened and was revealed in those 80 or so years is there came further experimental confirmation, theorems and evidence that we are in serious error somewhere(see list of assumptions).

Sure, some errors were found eg Von-Neumann's no go theorem on hidden variables was false. But we have no evidence we are still in serious error anywhere - we may be as research progresses - but may not as well. You are falling for Feynman's trap and assuming things. Experiment is the rock bottom essence - any theory that conforms to that is fine. It does not depend on the way a person views the world, what they believe, what they find elegant etc. Some cases of reformulation of a theory supersedes previous theories. It's because its more general, easier to extend etc - but strictly speaking that does not disprove the previous theory - it simply makes life easier for physicists so becomes the accepted view. Within that limited paradigm you can discuss which view is better. Note however some theories like LET that fits that category virtually nobody uses, so on this forum we have banned discussing it - SR, having no unobservable aether is better suited for extension to QFT and GR. That does not preclude discussing genuine peer reviewed scientific theories like GLET,

Thanks
Bill
 
Physics news on Phys.org
  • #37
bhobba said:
Sure, some errors were found eg Von-Neumann's no go theorem on hidden variables was false. But we have no evidence we are still in serious error anywhere - we may be as research progresses - but may not as well. You are falling for Feynman's trap and assuming things. Experiment is the rock bottom essence - any theory that conforms to that is fine. It does not depend on the way a person views the world, what they believe, what they find elegant etc.
I am not assuming anything, maybe you are.

Calling the deep foundational and conceptual problems a minor inconveniece is a gross understatement and misunderstanding.

It has been almost a century and quantum theory still lacks ontology(and for a reason). In fact, it's gotten ridden with more paradoxes. We now know quantum theory is correct and classical concepts outdated and wrong(although useful in a certain domain and perspective).

There is overwhelming evidence there is no coming back to the old concepts of immutable particles in time and space and afaik no research is being carried out in this direction.
 
  • #38
EPR said:
Calling the deep foundational and conceptual problems a minor inconveniece is a gross understatement and misunderstanding.

That there are foundational problems in QM is a matter of opinion. You are making an assumption there definitely is. That is not a universally held opinion. For example see:
https://www.amazon.com/dp/B008ABSSIW/?tag=pfamazon01-20.
Just a friendly bit of advice from a mentor, your personal opinions may not be universally accepted.

Thanks
Bill
 
  • Like
Likes Mentz114
  • #39
All the approaches to unification get stuck in the question of what's fundamental(since matter, space and time aren't - they are context dependent in both QM, QFT and SR). There are no non-contextual 'particles' or properties as such.

I would refer everyone to my previous post:

Relativistic quantum fields and superpositions, brain(eyes + visual cortex), classical perception('particles'). Somewhere along the chain lies the measurement problem and the issue of Bohr's complimentarity(unobservable waves of probability and definite outcomes aka observable 'particles').
 
Last edited:
  • #40
EPR said:
[..]
In fact, it's gotten ridden with more paradoxes.
[..]
That's interesting. Can you list them ?
 
  • #41
Mentz114 said:
That's interesting. Can you list them ?

It's all interpretation and opinion dependent. For example the claim 'That everything in nature can be reduced to interactions of the smallest particles' is false, IMHO runs into what we know from QFT, where particles and fields are really the same thing. However fully fleshing it out requires a new thread. A lot of other claims are really philosophy in my opinion - but again it needs fleshing out. There is nothing wrong holding such views, and you can discuss them here (providing it's not really just philosophy), but saying it's definitely true is not really in the scientific spirit. As a mentor, unless it gets bad I would not consider it actionable, however its wise to keep in mind what the situation actually is. I find knowing about various different interpretations helpful in understanding claims like that made previously.

Thanks
Bill
 
Last edited:
  • Like
Likes Mentz114
  • #42
bhobba said:
It's all interpretation and opinion dependent. For example the claim 'That everything in nature can be reduced to interactions of the smallest particles' is false, IMHO runs into what we know from QFT, where particles and fields are really the same thing. However fully fleshing it out requires a new thread. A lot of other claims are really philosophy in my opinion - but again it needs fleshing out. There is nothing wrong holding such views, and you can discuss them here (providing it's not really just philosophy), but saying it's definitely true is not really in the scientific spirit. As a mentor, unless it gets bad I would not consider it actionable, however its wise to keep in mind what the situation actually is. I find knowing about various different interpretations helpful in understanding claims like that made previously.

Thanks
Bill
Agreed.

I think the claim that 'QT has contradictions' is unsupported and there is no list.
 
  • #43
Mentz114 said:
That's interesting. Can you list them ?
You cut out and edited my post to remove the context but i will post it again here as conrext is crucial when discussing a cut out sentence.
It has been almost a century and quantum theory still lacks ontology(and for a reason). In fact, it's gotten ridden with more paradoxes. We now know quantum theory is correct and classical concepts outdated and wrong(although useful in a certain domain and perspective).

The paradoxes arise out of the lack of ontology. And the continued supporting evidence of standard quantum mechanics over classical mechanics post 1940(some new theorems and verifications have come about since giving further credence).
I stated earlier that i consider the Measurement Problem possibly the biggest mystery in science. But nobody is quoting that statement?
 
Last edited:
  • #44
EPR said:
The paradoxes arise out of the lack of ontology.

Ontology - the branch of metaphysics dealing with the nature of being. Being - existence. If QM has no existence then I do not know what theory does. Remember theories are not things that exist out there in the world, they are descriptions of things things that do. Now the nature of that existence is up for philosophical debate - but that is a question for a philosophy forum - not here.

Thanks
Bill
 
  • #45
EPR said:
You cut out and edited my post to remove the context but i will post it again here as conrext is crucial when discussing a cut out sentence.

The paradoxes arise out of the lack of ontology. And the continued supporting evidence of standard quantum mechanics over classical mechanics post 1940(some new theorems and verifications have come about since giving further credence).
I stated earlier that i consider the Measurement Problem possibly the biggest mystery in science. But nobody is quoting that statement?
I do not agree that the MP is a mystery. The fact that QT only predicts probabilities means that QT ( ie unitary evolution) cannot predict the outcome of an experiment any more than a thermometer can meaure length. This only a problem if it is assumed ( incorrectly) that probability has any existence other than in our calculations.
 
  • #46
Mentz114 said:
I do not agree that the MP is a mystery. The fact that QT only predicts probabilities means that QT ( ie unitary evolution) cannot predict the outcome of an experiment any more than a thermometer can meaure length. This only a problem if it is assumed ( incorrectly) that probability has any existence other than in our calculations.
There are no particles.

This way of thinking(that particles have properties before measurement and we are just ignorant) is 19 century talk. You don't care what it is you are measuring right? As long as it produces results in agreement with the formalism made to reflect said behavior?
 
Last edited:
  • #47
EPR said:
There are no particles.

This way of thinking(that particles have properties before measurement and we are just ignorant) is 19 century talk. You don't care what it is you are measuring right? As long as it produces results in agreement with the formalism made to reflect said behavior?
Even if the only particles that exist are the ones in our calculation then predicting results correctly means the theory is working. Assuming that this or that element in the calculation actually exists is speculative for anything that is below a certain size.

Which means that dialectic on this subject reduces to opinions about what exists and what does not.
 
  • Like
Likes bhobba
  • #48
Mentz114 said:
Which means that dialectic on this subject reduces to opinions about what exists and what does not.

And BM has a different take. This is one of the genuine issues with QM. Its difficult to say anything concrete about some things because there is an interpretation where its not true. I even fall for it on occasion such as when I explain entanglement. Once particles are entangled you can't speak about their individuality - but in BM you can - it really makes this 'semantically' difficult.

Thanks
Bill
 
  • Like
Likes Mentz114
  • #49
BM is not taught in textbooks and due to its added 'baggage' is not part of any university curriculum.

Is it relativistically invariant?
 
  • #50
bhobba said:
Bohr's answer, and even the answer I would give, is not at all satisfying even though I think its true. Its the very essence of quantum weirdness.:
https://arxiv.org/abs/0911.0695
You simply can't have other desirable properties without it.

Thanks
Bill
I’m confused by something in that paper. They write:
In this work we have shown that classical probability theory and quantum theory – the only two probability theories for which we have empirical evidences — are special in a way that they fulfill three reasonable axioms on the systems’ information carrying capacity, on the notion of locality and on the reversibility of transformations. The two theories can be separated if one restricts the transformations between the pure states to be continuous. An interesting finding is that quantum theory is the only non-classical probability theory that can exhibit entanglement without conflicting one or more axioms. Therefore – to use Schro ̈dinger’s words – entanglement is not only “the characteristic trait of quantum mechanics, the one that enforces its entire departure from classical lines of thought”, but also the one that enforces the departure from a broad class of more general probabilistic theories.

So, axiom 3 (Reversibility) alone distinguishes classical probability theory (CPT) and quantum theory, but they also write that:
As we will see later, taking the latter choice, it will follow from axiom 1 alone that the state space must contain entangled states.
So, from this statement and the fact that axiom 3 alone distinguishes CPT from QT, I infer that classical probability theory contains entangled states. But, that is at odds with entanglement as “the characteristic trait of quantum mechanics, the one that enforces its entire departure from classical lines of thought”.

What am I missing?
 
  • #51
RUTA said:
What am I missing?

I think you may have picked up a logical issue with the paper - at least a badly expressed idea. It says 'An interesting finding is that quantum theory is the only non-classical probability theory that can exhibit entanglement without conflicting one or more axioms.'

It has not ruled out entanglement in classical probability theory - but for the life of me I can't think of how classical probability theory can have entanglement. It has me beat. In fact the following paper states it outright:
http://staff.utia.cas.cz/swart/lecture_notes/qua17_04_05.pdf
' In classical probability, entangled states do not exist'

Thanks for your careful reading - I should have spotted it - but didn't.

Someone else may be able to disentangle (pun intended) the intent - but I can't see it at the moment.

Thanks
Bill
 
Last edited:
  • #52
bhobba said:
I think you may have picked up a logical issue with the paper - at least a badly expressed idea. It says 'An interesting finding is that quantum theory is the only non-classical probability theory that can exhibit entanglement without conflicting one or more axioms.'

It has not ruled out entanglement in classical probability theory - but for the life of me I can't think of how classical probability theory can have entanglement. It has me beat. In fact the following paper states it outright:
http://staff.utia.cas.cz/swart/lecture_notes/qua17_04_05.pdf
' In classical probability, entangled states do not exist'

Thanks for your careful reading - I should have spotted it - but didn't.

Someone else may be able to disentangle (pun intended) the intent - but I can't see it at the moment.

Thanks
Bill
I just emailed Professor Dakic, perhaps someone in his group will clarify their use of the terminology in that paper. I'll let you know what they say :-)
 
  • Like
Likes vanhees71 and bhobba
  • #53
RUTA said:
I just emailed Professor Dakic, perhaps someone in his group will clarify their use of the terminology in that paper. I'll let you know what they say :-)
Here is Dakic's reply:
the sentence in question: "As we will see later, taking the latter choice, it will follow from axiom 1 alone that the state space must contain entangled states." refers to the previous: ...also called “generalized bit”. So, the logic is that any 1 bit-system obeying Axiom 1 is either: a) discrete (and in this case only classical bit is a consistent solution) or b) continuous (such as real, quantum or some general bit). In the latter case, entanglement is the necessary feature. The only counter-example to this is the classical bit and consequently classical probability theory. They do not exhibit entanglement.
Here is the entire paragraph, so that his reply makes more sense:
In logical terms axiom 1 means the following. We can think of two basis states as two binary propositions about an individual system, such as (1) “The outcome of measurement A is +1” and (2) “The outcome of measurement A is -1”. An alternative choice for the pair of propositions can be propositions about joint properties of two systems, such as (1’) “The outcomes of measurement A on the first system and of B on the second system are correlated” (i.e. either both +1 or both -1) and (2’) “The outcomes of measurement A on the first system and of B on the second system are anticorrelated”. The two choices for the pair of propositions correspond to two choices of basis states which each can be used to span the full state space of an abstract elementary system (also called “generalized bit”). As we will see later, taking the latter choice, it will follow from axiom 1 alone that the state space must contain entangled states.
So, yes, trivially the discrete (classical bit) option is an "entangled state" in the sense of the "alternative choice for the pair of propositions about joint probabilities," i.e., the outcomes are either correlated or anti-correlated. But, since there is no continuous mapping between such basis states in the classical case, there is no entanglement proper, as is well known. Thus, strictly speaking, I would say axiom 1 and axiom 3 are both required for entanglement. Maybe I'm missing something. What to the mathemagicians say?
 
  • Like
Likes akvadrako
<h2>1. What is entanglement in Bohr's idea of complementarity?</h2><p>Entanglement refers to the phenomenon in which two or more particles become connected in such a way that the state of one particle is dependent on the state of the other, even when they are physically separated. In Bohr's idea of complementarity, entanglement is seen as a fundamental aspect of quantum systems that cannot be fully understood or described using classical concepts.</p><h2>2. How does Bohr define complementarity?</h2><p>Bohr's idea of complementarity is based on the principle that certain physical quantities, such as position and momentum, cannot be measured simultaneously with precision. He argued that these quantities are complementary and cannot be fully described or understood without considering their interdependence. This concept is central to Bohr's interpretation of quantum mechanics and is closely related to the idea of entanglement.</p><h2>3. Is entanglement properly defined in Bohr's idea of complementarity?</h2><p>While Bohr's idea of complementarity is a widely accepted interpretation of quantum mechanics, there is ongoing debate about the proper definition of entanglement within this framework. Some argue that Bohr's definition is too limited and does not fully capture the complexity of entangled systems, while others believe it provides a useful understanding of entanglement in the context of complementarity.</p><h2>4. Can entanglement be observed in experiments?</h2><p>Yes, entanglement has been observed in numerous experiments, providing strong evidence for its existence. One of the most famous examples is the EPR paradox, which demonstrated that entanglement allows for instantaneous communication between particles, violating the speed of light limit.</p><h2>5. How does entanglement impact our understanding of the nature of reality?</h2><p>Entanglement challenges our traditional understanding of reality, as it suggests that particles can be connected in ways that defy our classical understanding of space and time. It also raises questions about the role of consciousness and observation in shaping reality, as entanglement is often seen as a manifestation of the observer effect in quantum mechanics.</p>

1. What is entanglement in Bohr's idea of complementarity?

Entanglement refers to the phenomenon in which two or more particles become connected in such a way that the state of one particle is dependent on the state of the other, even when they are physically separated. In Bohr's idea of complementarity, entanglement is seen as a fundamental aspect of quantum systems that cannot be fully understood or described using classical concepts.

2. How does Bohr define complementarity?

Bohr's idea of complementarity is based on the principle that certain physical quantities, such as position and momentum, cannot be measured simultaneously with precision. He argued that these quantities are complementary and cannot be fully described or understood without considering their interdependence. This concept is central to Bohr's interpretation of quantum mechanics and is closely related to the idea of entanglement.

3. Is entanglement properly defined in Bohr's idea of complementarity?

While Bohr's idea of complementarity is a widely accepted interpretation of quantum mechanics, there is ongoing debate about the proper definition of entanglement within this framework. Some argue that Bohr's definition is too limited and does not fully capture the complexity of entangled systems, while others believe it provides a useful understanding of entanglement in the context of complementarity.

4. Can entanglement be observed in experiments?

Yes, entanglement has been observed in numerous experiments, providing strong evidence for its existence. One of the most famous examples is the EPR paradox, which demonstrated that entanglement allows for instantaneous communication between particles, violating the speed of light limit.

5. How does entanglement impact our understanding of the nature of reality?

Entanglement challenges our traditional understanding of reality, as it suggests that particles can be connected in ways that defy our classical understanding of space and time. It also raises questions about the role of consciousness and observation in shaping reality, as entanglement is often seen as a manifestation of the observer effect in quantum mechanics.

Similar threads

  • Quantum Interpretations and Foundations
6
Replies
175
Views
5K
  • Quantum Interpretations and Foundations
Replies
2
Views
1K
  • Quantum Interpretations and Foundations
2
Replies
37
Views
1K
  • Quantum Interpretations and Foundations
Replies
7
Views
1K
  • Quantum Interpretations and Foundations
3
Replies
84
Views
1K
  • Quantum Interpretations and Foundations
3
Replies
76
Views
5K
  • Quantum Interpretations and Foundations
2
Replies
54
Views
3K
Replies
41
Views
2K
  • Quantum Interpretations and Foundations
Replies
1
Views
398
  • Quantum Interpretations and Foundations
Replies
27
Views
2K
Back
Top