1) You are over complicating the situation. Either A or B is "observed" first and the other is then locked into a valueTMO said:Suppose I have an apparatus A that is entangled with apparatus B. In my reference frame, I observe apparatus A, which simultaneously causes apparatus B to do its thing. However, because there exists a reference frame where apparatus B does its thing before apparatus A, it follows that there exists a reference frame in which B does its thing before it was caused by A to do so.
atyy said:Quantum entanglement does violate the classical notion of relativistic causality, if the wave function is considered real. This is the content of Bell's theorem.
However, quantum entanglement does not violate signal causality, ie. it does not allow classical information to be sent faster than light.
TMO said:Thanks for informing me that quantum entanglement does violate the classical notion of relativistic causality. It's good that you included the bit about signal causality, but I already knew that, mostly because every layman article on QM includes it.
TMO said:I observe apparatus A, which simultaneously causes apparatus B to do its thing..
TMO said:Suppose I have an apparatus A that is entangled with apparatus B. In my reference frame, I observe apparatus A, which simultaneously causes apparatus B to do its thing. However, because there exists a reference frame where apparatus B does its thing before apparatus A, it follows that there exists a reference frame in which B does its thing before it was caused by A to do so.
Why are physicists so willing to abandon the idea that the things they talk about are real? But, like hippies on acid, they do.atyy said:The alternative, if the wave function is not considered real and we explicitly exclude hidden variables, then classical relativistic causality may be considered "empty" or "meaningless" so that there is no formal violation.
Derek Potter said:Why are physicists so willing to abandon the idea that the things they talk about are real?
I'm not sure what that means. How can particles be entangled when there are no particles?DrChinese said:There are experiments in which - conforming with your example - particles are entangled AFTER they cease to exist in all reference frames.
TMO said:... I observe apparatus A, which simultaneously causes apparatus B to do its thing.
Nobody's forcing them. Yet they do it.bhobba said:They aren't unless forced to.
Only because they've been panicked into playing at philosophy. It ends up as sophistry that obscures the fact that physics has discovered some interesting, weird even, facts about nature. It needn't be so. Rather than getting stirred up about what it means to be real, it is far more useful to ask what the real world is like.bhobba said:But getting everyone to agree on that is a lost cause.
Derek Potter said:Nobody's forcing them. Yet they do it.
Derek Potter said:My view: reality is a primitive,
Derek Potter said:Thus local causality is violated in the real world
So you are going to ask what the "real" world is like without worrying about what "real" means? How do you do that?Derek Potter said:Rather than getting stirred up about what it means to be real, it is far more useful to ask what the real world is like.
By experiment and models, same as in any other science.phinds said:So you are going to ask what the "real" world is like without worrying about what "real" means? How do you do that?
No, that is not how it is done in ANY science. You cannot do experiments or make models for something that is undefined.Derek Potter said:By experiment and models, same as in any other science.
Derek Potter said:By experiment and models, same as in any other science.
And neither would I attempt to do so. Nobody investigates whether the real world is real.phinds said:No, that is not how it is done in ANY science. You cannot do experiments or make models for something that is undefined.
Derek Potter said:Nobody investigates whether the real world is real.
Yes, it's a tautology.bhobba said:You do know what a tautology is don't you?
Then why are you wasting our time with it?Derek Potter said:Yes, it's a tautology.
Oh yes you do. I'm trying to wean you off it by saying that "real" has the same meaning in physics as it has in everyday life. Everybody knows what it means but nobody can define it. And there's a good reason for that - it isn't a property. A goblin that doesn't exist is not a particular type of goblin. If that is philosophy, so be it, we certainly have to use a homeopathic amount of philosophy to cure a pathological infection.bhobba said:Really this is an issue in philosophy, not science, and we don't discuss philosophy here.
Why are you wasting my time talking about scientific investigation of the meaning of "real"?phinds said:Then why are you wasting our time with it?
bhobba said:Well first you need to show locality applies to correlations which the cluster decomposition property excludes. The truth of it is its all semantic verbiage depending on freely chosen definitions.
atyy said:Cluster decomposition does apply to correlations.
bhobba said:
atyy said:Yes, I know that discussion. The pertinent part there is that Weinberg's informal statement of cluster decomposition is too sloppy (clearly violating quantum mechanics if correlations are included - if correlations are not included, then it is a tautology - there are no correlations when there are no correlations). A better informal definition of cluster decomposition would have been "no faster than light signalling". This applies to all states.
Quantum entanglement occurs when two or more particles become connected in such a way that the state of one particle affects the state of the other, regardless of the distance between them.
Quantum entanglement does not violate causality because although the states of the entangled particles are correlated, the actions on one particle do not cause a direct effect on the other. Instead, the entangled particles share a common quantum state, and any changes to this state will affect both particles simultaneously.
No, information cannot be transmitted through quantum entanglement. Although the states of the entangled particles are correlated, they cannot be used to transmit information faster than the speed of light.
Yes, quantum entanglement has a variety of practical applications, including quantum cryptography, quantum teleportation, and quantum computing.
Quantum entanglement is being studied and utilized in current research through various experiments and studies in quantum mechanics and quantum information theory. Some researchers are also exploring its potential applications in areas such as communication, computing, and cryptography.