What's so strange about entangled particles?

In summary: So what the first observer measures affects what the second observer will find, but it's not predetermined.
  • #1
kent davidge
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In a thought experiment, there is a spin-0 source emitting particles. (I suppose you already know what is that experiment.) Two observers in opposite sides along the same axis measure opposite spin components. If one observer measure, say, spin up, then the second observer will certainly measure spin down. Then it's said that the measurement by one observer affects what the another observer will find. But why don't conclude that the system (composed by the two particles) was already set up for that particular pair of results (spin up to one particle and down to the other particle) before the first observer interact with the system?
 
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  • #2
You're thinking of spin-1/2 particles because the spin can take two values. Anyway, the explanation you gave falls flat on its face when you consider more general measurements on each particle. This is called Bell's theorem. But you are right that if you measure the spin of both particles in the same direction, then it's no different than classical correlation.
 
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  • #3
Truecrimson
I got this. Thank you.
 
  • #4
The correlation depends on the basis in which both the measurements are made. The basis can freely be adjusted at any time. So since the basis can be freely adjusted and the results depend on the basis, then if the results are predetermined, the choice of basis must be predetermined, and experimenters have no free will.
 
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  • #5
entropy1 said:
The correlation depends on the basis in which both the measurements are made. The basis can freely be adjusted at any time. So since the basis can be freely adjusted and the results depend on the basis, then if the results are predetermined, the choice of basis must be predetermined, and experimenters have no free will.
So why is quantum entanglement considered mysterious?
 
  • #6
I guess some find that the correlation between the measurement outcomes of a pair of separated particles looks like transfering of information faster than light (non-locality), which is impossible. However, since there is no causal relationship, relativitiy is not violated. The absence of causality between correlated outcomes is mysterious too. :smile:
 
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  • #7
kent davidge said:
So why is quantum entanglement considered mysterious?
David Mermin gave a simple example of a hypothetical Bell's Theorem experiment in this article:

Is the moon there when nobody looks? Reality and the quantum theory (PDF file)

Read the description carefully, study the results, and see if you can come up with a "non-mysterious" explanation.
 
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  • #8
kent davidge said:
So why is quantum entanglement considered mysterious?
Good question. There's nothing mysterious with it on the level of the pure physics part of quantum theory, but it is the very phenomenon that makes quantum theory very different from classical physics, and we are used to classical physics in our everyday experience (except for the fact that matter is stable, which is not understandable at all within classical physics).
 
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  • #9
  • #10
kent davidge said:
... But why don't conclude that the system (composed by the two particles) was already set up for that particular pair of results (spin up to one particle and down to the other particle) before the first observer interact with the system?

Because, according to QM, the outcome could have been the opposite (spin down to one particle and up to the other particle).
 

Related to What's so strange about entangled particles?

1. What is entanglement?

Entanglement is a phenomenon in quantum mechanics where 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 separated by large distances. This means that measuring the state of one particle will instantly determine the state of the other, regardless of the distance between them.

2. How do particles become entangled?

Particles can become entangled through interactions with each other, such as collisions or through the process of decay. They can also become entangled through the process of quantum teleportation, where the state of one particle is transferred to another without any physical connection between them.

3. What makes entanglement so strange?

The strangeness of entanglement lies in the fact that it violates our classical understanding of the world. In classical physics, objects have definite properties that exist independently of our observation. However, in quantum mechanics, the properties of particles are not well-defined until they are measured. Entanglement highlights this strange behavior, as the state of one particle cannot be determined without measuring the state of the other, even if they are separated by vast distances.

4. How is entanglement useful?

Entanglement has many potential applications in quantum computing, cryptography, and communication. In quantum computing, entanglement allows for the creation of superposition states, which can be used to perform multiple calculations simultaneously. In cryptography, entangled particles can be used to create unbreakable codes, as any attempt to intercept or measure the particles would alter their state. In communication, entanglement can be used to transmit information instantly, regardless of the distance between the particles.

5. Can entanglement be explained by classical physics?

No, entanglement is a purely quantum phenomenon that cannot be explained by classical physics. It challenges our understanding of the universe and highlights the fundamental differences between classical and quantum mechanics. While classical physics can describe the behavior of large-scale objects, it fails to explain the strange behavior of particles on a microscopic scale, such as entanglement.

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