The discussion centers around the concept of whether entangled particles can enable instantaneous communication. Participants explore the implications of entanglement in quantum mechanics, particularly in relation to the no communication theorem and the nature of measurement in quantum states.
Participants generally agree that entangled particles cannot be used for instantaneous communication, but multiple competing views exist regarding the implications of entanglement and measurement in quantum mechanics. The discussion remains unresolved on the nuances of these interpretations.
Limitations include the dependence on interpretations of quantum mechanics and the unresolved nature of how entanglement and measurement interact. The discussion reflects various levels of understanding and misconceptions about the nature of entanglement.
This discussion may be useful for individuals interested in quantum mechanics, particularly those exploring the implications of entanglement and communication theories within the field.
PeterPendragon said:If entangled pairs can be used to communicate instantaneously, does that mean one of the paired particles has to be physically delivered to the reception point in order to establish communication?
Even if you would know that, you cannot use it for instantaneous communication. While a proper quantum mechanical description is a bit more complicated, here is a classical analogy that captures the relevant features: Write "yes" on one paper and "no" on another, put them in separate identical-looking envelopes and mix them, then give the envelopes to people far away. Before you open the envelopes you don't know which answer you will find. You know whenever someone opens the envelope and sees "yes" or "no", then the other envelope will have the opposite answer. But you cannot influence that answer, so you cannot use it for communication.jfizzix said:...then there is no way of telling if these particles are halves of entangled pairs or not.
Thanks. I get that, but I thought if you altered the state of one pair (eg spin), you changed the other, hence communication?mfb said:Even if you would know that, you cannot use it for instantaneous communication. While a proper quantum mechanical description is a bit more complicated, here is a classical analogy that captures the relevant features: Write "yes" on one paper and "no" on another, put them in separate identical-looking envelopes and mix them, then give the envelopes to people far away. Before you open the envelopes you don't know which answer you will find. You know whenever someone opens the envelope and sees "yes" or "no", then the other envelope will have the opposite answer. But you cannot influence that answer, so you cannot use it for communication.
PeterPendragon said:Thanks. I get that, but I thought if you altered the state of one pair (eg spin), you changed the other, hence communication?
In some interpretations you change the other, but you still cannot predict in which way you change it - you change it randomly (simplified description). You can measure that afterwards, but then you cannot change it any more.PeterPendragon said:Thanks. I get that, but I thought if you altered the state of one pair (eg spin), you changed the other, hence communication?
PeterPendragon said:Thanks. I get that, but I thought if you altered the state of one pair (eg spin), you changed the other, hence communication?
Entanglement is broken once you measure the entangled property.PeterPendragon said:And, why can't you "change it anymore"?
In some interpretations of quantum mechanics, not in all. That alone shows that you cannot transmit information.PeterPendragon said:I thought the whole point was that if you changed the state of a member of an entangled pair, it's partner also changes.
That's not how it works. If you change the spin of either member, the entanglement is broken. All entanglement says is that if you measure one member of the pair, then you know what the value of the the corresponding measurement on the other will be, when and if such a measurement is made - for all you know, that other measurement has already been made. Furthermore, it only works for the first measurement on each member - after that the entanglement is broken.PeterPendragon said:And, why can't you "change it anymore"? I thought the whole point was that if you changed the state of a member of an entangled pair, it's partner also changes.
"Sneaking a look at God's cards" by GianCarlo Girardi covers a lot more than just entanglement, but it's good and relatively simple.Could anyone recommend a good but relatively simple article or book I could read on this?