Energy conservation+superpositions=entanglement?

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Discussion Overview

The discussion revolves around the relationship between energy conservation, superposition in quantum systems, and entanglement. Participants explore how energy conservation applies in the context of quantum harmonic oscillators and the implications of wavefunction collapse during measurements.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • Some participants propose that a particle in a quantum harmonic oscillator can exist in a superposition of energy eigenstates, leading to an uncertainty in energy that must be balanced by uncertainty elsewhere in the universe.
  • Others argue that the uncertainty associated with a superposition state is not related to other systems, and that energy conservation in this context refers to the expectation value of energy.
  • A later reply questions how energy is accounted for when the wavefunction collapses, noting that this can lead to significant changes in the expectation value of energy.
  • One participant suggests that bringing a system into contact with a measurement apparatus makes it an open system, which may lead to energy not being conserved in the traditional sense.
  • Another participant draws a parallel to classical entanglement scenarios, mentioning angular momentum conservation in the context of emitted photons, and hints at a connection to entanglement arguments.
  • Some participants discuss the interpretation of entangled states in relation to measurement and the challenges posed by different interpretations of quantum mechanics, such as the Copenhagen interpretation.
  • One participant concludes that in practice, it may be sufficient to assume that the energy expectation value of the system is conserved, while acknowledging that measurement can exchange energy with the system.

Areas of Agreement / Disagreement

Participants express varying views on the relationship between superposition, entanglement, and energy conservation, with no consensus reached on how these concepts interrelate. The discussion remains unresolved regarding the implications of wavefunction collapse and the interpretation of entangled states.

Contextual Notes

Limitations include the dependence on interpretations of quantum mechanics, the ambiguity surrounding the effects of measurement on energy conservation, and the unresolved nature of how entanglement is defined in different contexts.

Scott Hill
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A particle in a quantum harmonic oscillator can be in a superposition of energy eigenstates, and so the energy is not well-defined. However, energy is still conserved, so if I understand it correctly the "uncertainty" in the superposition's energy must be matched by uncertainty elsewhere in the Universe. is this entanglement we're talking about here, or is there another explanation for how energy conservation works here?
 
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Scott Hill said:
A particle in a quantum harmonic oscillator can be in a superposition of energy eigenstates, and so the energy is not well-defined. However, energy is still conserved, so if I understand it correctly the "uncertainty" in the superposition's energy must be matched by uncertainty elsewhere in the Universe.
The uncertainty associated with a superposition state of a certain system isn't related to other systems in any way.

On the other hand, if you have two systems in an entangled state, you cannot assign definite state vectors to the individual systems in the first place. Look up the difference between "pure" and "mixed" states if you are interested in this.

Scott Hill said:
or is there another explanation for how energy conservation works here?
If you don't have a definite energy, energy conservation refers to the expectation value of energy.
 
Last edited:
kith said:
The uncertainty associated with a superposition state of a certain system isn't related to other systems in any way.

On the other hand, if you have two systems in an entangled state, you cannot assign definite state vectors to the individual systems in the first place. Look up the difference between "pure" and "mixed" states if you are interested in this.If you don't have a definite energy, energy conservation refers to the expectation value of energy.

OK. Collapsing the wavefunction can cause a dramatic change in the expectation value of the energy, though; how is that energy accounted for?

Thanks.
 
Scott Hill said:
OK. Collapsing the wavefunction can cause a dramatic change in the expectation value of the energy, though; how is that energy accounted for?
First of all, bringing your system into contact with a measurement apparatus makes it an open system, so its energy need not be conserved. Naturally, one would try to use a full description including the apparatus and see what happens there. But then, you unfortunately run into all the well-known problems of the foundations of QM.

Also that the expectation value changes dramatically when you perform a measurement happens already in classical statistical mechanics. I'm not saying that QM is completely analogous but if the state somehow encodes subjective information, this behaviour is not so surprising.

I'm afraid I don't have a clearer answer to your question.
 
OK, I've got it I think. It reminded me of the classic entanglement problem where an atom emits two circularly-polarized photons in opposite directions: angular momentum conservation forces the two particles to have opposite polarizations. I think there's still an "entanglement" argument to be made in there somewhere, but I'll think about it some more. Thanks!
 
If you use a full quantum description for the system and the apparatus, you do get entanglement between the two which is relevant for your question. The problem lies in how this entangled state should be interpreted. It doesn't connect well with the pragmatical Copenhagen point of view on QM.
 
Ah good, that's what I was thinking. But in *practice* we can just assume that it's the energy expectation value of the system that's conserved, and that measurement can exchange energy with the system.

Great! It's funny the questions that only occur to me once I have to teach a subject. :)
 

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