Space and time dependence of entangled particles

In summary, entanglement of two particles does not change with time and can cross long distances without decoherence from the environment. It is possible for the wave function of entanglement to have time and space dependence, as long as it maintains the correlation between the properties of the particles. Entanglement is a property of the wave function for the entire system, not a relationship between different wave functions for different properties. Therefore, the wave function for the entire system can still vary in time and space while preserving the entanglement.
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friend
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It seems that the entanglement of two particles does not change with time and can cross long distanced as long an neither particle decoheres with the environment. This makes me wonder if the wave function for that entanglement can have any time or space dependence? I only did a brief search for time dependent entanglement and found nothing. Any help would be appreciated.
 
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friend said:
This makes me wonder if the wave function for that entanglement can have any time or space dependence?

The short answer is yes, it can--as long as whatever time and space dependence exists preserves whatever correlation between the properties of the two particles is guaranteed by the entanglement. For example, if two particles are entangled to have opposite spins (total spin zero), then the wave function for the two-particle system can still change in time and space, as long as it still has total spin zero.

The longer answer is to remember that, for a system containing two particles, you don't have two wave functions, one for each particle: you have one wave function for the whole system, which contains degrees of freedom associated with both particles. (In fact, you can even have entanglement between different degrees of freedom of a single particle, for example between its position or momentum and its spin: the key thing is having more than one degree of freedom, not more than one particle.) "Entanglement" is a property of the wave function for the whole system, not a relationship between different wave functions for different properties. So the wave function for the whole system can still vary in time and space, as long as it preserves the entanglement property.
 
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Thank you.
 

Related to Space and time dependence of entangled particles

1. What is entanglement in the context of space and time?

Entanglement refers to 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, regardless of the distance between them. This means that the particles are no longer considered separate entities, but rather a single system with shared properties.

2. How does entanglement affect the behavior of particles in space and time?

Entanglement can affect the behavior of particles in space and time by allowing them to exhibit correlated behavior, even when separated by large distances. This means that changes in the state of one particle can instantaneously affect the state of the other, regardless of the distance between them.

3. Can entanglement be used for communication or faster-than-light travel?

No, entanglement cannot be used for communication or faster-than-light travel. While changes in the state of one particle can affect the state of the other instantaneously, there is no way to control or predict these changes. Therefore, entanglement cannot be used to transmit information or travel faster than the speed of light.

4. How does the space and time dependence of entangled particles relate to the concept of quantum non-locality?

The space and time dependence of entangled particles is closely related to the concept of quantum non-locality. Non-locality refers to the idea that entangled particles can exhibit correlated behavior regardless of the distance between them, violating the classical notion of locality. This is possible because entangled particles are no longer considered separate entities, but rather a single system with shared properties.

5. What are the potential applications of understanding the space and time dependence of entangled particles?

Understanding the space and time dependence of entangled particles has potential applications in various fields, such as quantum computing, cryptography, and communication. It could also lead to a better understanding of fundamental physics and the nature of reality. Additionally, studying entanglement could help us develop new technologies and methods for information processing and communication.

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