I EPR revisited

  • I
  • Thread starter Thread starter anuttarasammyak
  • Start date Start date
Click For Summary
In an inertial frame of reference, entangled particles A and B exhibit a state that collapses upon measurement at A, leading to a frame-dependent interpretation of B's state. The relativity of simultaneity complicates the assertion that B possesses a specific state at the same time as A's measurement, as this timing can vary across different frames. The discussion highlights that specifying an event requires a defined time and place, which is not invariant across frames. Furthermore, the concept of state collapse in quantum mechanics lacks a consistent definition within a relativistic framework, raising questions about the intuitive understanding of quantum events. Overall, the conversation emphasizes the complexities of integrating quantum mechanics with relativity, particularly regarding simultaneity and state definitions.
anuttarasammyak
Gold Member
Messages
2,958
Reaction score
1,521
In an inertial frame of reference (IFR), there are two fixed points, A and B, which share an entangled state
$$ \frac{1}{\sqrt{2}}(|0>_A|1>_B+|1>_A|0>_B) $$
At point A, a measurement is made. The state then collapses to
$$ |a>_A|b>_B, \{a,b\}=\{0,1\} $$

We assume that A has the state ##|a>_A## and B has ##|b>_B## simultaneously, i.e., when their synchronized clocks both read time T

However, in other inertial frames, due to the relativity of simultaneity, the moment when B has ##|b>_B## occurs when B’s clock reads a time before or after T

Therefore, may we conclude that the statement “B has ##|b>_B##" is not invariant, but frame-dependent?
 
Last edited:
Physics news on Phys.org
anuttarasammyak said:
may we conclude that the statement “B has ##|b>_B##" is not invariant, but frame-dependent?
You may conclude that that statement, as you make it, is not even well-defined. You didn't specify a time in any frame at which B has that state.

A true statement would be that the time ordering of spacelike separated events is not invariant, but frame-dependent. But specifying an event requires specifying a place and a time in some frame--an event is a point in spacetime.

You are also sweeping under the rug complications that involve quantum mechanics as well as relativity. For example, suppose we say that the measurement on A happens at a particular event--a particular place and time in some chosen frame. You are assuming that the state of B collapses when the measurement on A is made. But at what event does the collapse of B happen? There is no invariant way to specify that--which should be a clue that the intuitive picture of QM you are using is not, in fact, correct--more precisely, it is not relativistic. In relativistic QM, i.e., quantum field theory, the whole idea of "collapse" is much more problematic, because there are no invariant answers to questions like the one I posed just now.

In short, you unfortunately have chosen a bad example to illustrate the relativity of simultaneity.
 
Reply
  • Like
Likes anuttarasammyak
Thank you @PeterDonis. I should be somewhat satisfied to know that studies are going on.
 
anuttarasammyak said:
I should be somewhat satisfied to know that studies are going on.
I'm not sure what "studies" you're referring to, but it's certainly true that there have been plenty of experiments testing both relativity of simultaneity and the QM predictions for measurements on entangled particles.
 

Thread 'Euclidean geometry and gravity'

I asked a question here, probably over 15 years ago on entanglement and I appreciated the thoughtful answers I received back then. The intervening years haven't made me any more knowledgeable in physics, so forgive my naïveté ! If a have a piece of paper in an area of high gravity, lets say near a black hole, and I draw a triangle on this paper and 'measure' the angles of the triangle, will they add to 180 degrees? How about if I'm looking at this paper outside of the (reasonable)...
View full post »

Thread 'Jackson: justification of the Poynting vector by GR'

The Poynting vector is a definition, that is supposed to represent the energy flow at each point. Unfortunately, the only observable effect caused by the Poynting vector is through the energy variation in a volume subject to an energy flux through its surface, that is, the Poynting theorem. As a curl could be added to the Poynting vector without changing the Poynting theorem, it can not be decided by EM only that this should be the actual flow of energy at each point. Feynman, commenting...
View full post »
Thread 'Relativity of simultaneity in actuality'

Thread 'Relativity of simultaneity in actuality'

I’m attaching two figures from the book, Basic concepts in relativity and QT, by Resnick and Halliday. They are describing the relativity of simultaneity from a theoretical pov, which I understand. Basically, the lightning strikes at AA’ and BB’ can be deemed simultaneous either in frame S, in which case they will not be simultaneous in frame S’, and vice versa. Only in one of the frames are the two events simultaneous, but not in both, and this claim of simultaneity can be done by either of...
View full post »

Similar threads

Problem with a basic theorem in Wald's GR book
Replies
8
Views
2K
I Solving Length Contraction Paradox
Replies
3
Views
2K
A Synchronous to Newtonian gauge
Replies
1
Views
975
I Pullback & orthogonal projector
Replies
2
Views
747
Proper time in moving frame of reference
Replies
5
Views
2K
Relation between Mutual information and Expectation Values
Replies
2
Views
808
I Understanding Relativity of Simultaneity in Resnick, Part II
Replies
20
Views
2K
I How does an arbitrary choice of the origin affect real observations?
Replies
15
Views
1K
I Christoffel's symbols: symmetry in the two (lower) indices
Replies
6
Views
6K
I Help understanding conditional expectation identity
Replies
1
Views
2K