mfb- t1_jdu3qaz wrote
In principle you can entangle as many particles as you want. A prominent example is the GHZ state. You can also get entanglement with effective particles like phonons where you could say the entanglement includes the whole object.
The more particles you include the harder it tends to get to preserve entanglement.
> Where two particles interact regardless of the physical distance between them.
They don't interact with each other.
> can this be expanded [...] to observe things like additional dimensions or new physics?
No.
the_fungible_man t1_jdu7skt wrote
I read the article you linked, and achieved 0% comprehension, which made me wonder, how esoteric is the information it presented? Pretty basic for physics post-grad students? Or only those with advanced degrees specifically in more narrow physics specialties?
mfb- t1_jdu8hgd wrote
The state itself should be easy to understand after a course on quantum mechanics, so hopefully for most with a BSc in physics. The state is a superposition of these two options "all particles are in state 1" and "all particles are in state 0" (for some systems that have these two options for each particle). It's pretty similar to the typical example of two entangled particles where you have one particle in one state and the other in the other, or both in the same state. Just with a third particle.
the_fungible_man t1_jdu9l79 wrote
Thank you.
Blakut t1_jduspez wrote
so there is no |101> state?
TopologicalInsulator t1_jduxfr3 wrote
Not as part of the GHZ state, but you could of course make a |101> state on its own.
El_Sephiroth t1_jdzq8h1 wrote
More like |-1,0,1> because |101> would be |0>+2×|1> If I remember correctly
Mikesturant t1_jdu7w7c wrote
How many entangled particle groups can function independently of each other while still grouped.
If that makes sense.
Can you have multiple entanglements of different data in the same grouping or proximity
mfb- t1_jdu8nfp wrote
What do you mean by "function independently"?
> Can you have multiple entanglements of different data in the same grouping or proximity
Yes.
[deleted] t1_jdu9gox wrote
[removed]
Mikesturant t1_jdu9fe5 wrote
Nice. Like a fiber optic trunk cable. In essence.
Fenrisvitnir t1_jduev91 wrote
>How many entangled particle groups can function independently of each other while still grouped.
Not sure what you mean here - you can in theory cross-entangle entangled groups of particles, but I doubt that is what you are really asking.
Mikesturant t1_jduf5j1 wrote
I'm also not sure how to ask.
The entanglement is data or information? Yes?
dyrin t1_jdv1pgi wrote
Entanglement is data/information about the state of the particle at the moment of entanglement.
But they can't transfer any information after the entangled particles have been seperated.
Mikesturant t1_jdvon9w wrote
Isn't this the same as the Stanford lady and moving the light particles through empty space?
Fenrisvitnir t1_jdvvdm9 wrote
Entanglement is a constraint on information about the particles. ie. if one was spin up, the other must be spin down, but we don't know which is which.
Let me ask this question - are you thinking about sending information over optical fiber using paired photons? Entangled photons can't send information, there must always be a classical information pathway for networking applications.
Mikesturant t1_jdvvqj3 wrote
No the optical fiber remark was a comparison.
As a not physicist I'm wondering if the entanglement is being used with the condensate method of capturing photons and reproducing them in another space.
Blakut t1_jdusvyv wrote
afaik one can't even tell if two specific particles are entangled just by measuring them.
mfb- t1_jdv9ey7 wrote
For two particles you can't be sure, indeed, you can only tell from statistics if you have a large sample.
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