Heidi said:Hi Pfs
I read in the GHZ experiment article
that classical physics give an inéquality (a Bell like inequality)
Is there also sets of directions where this inequality is maximally violated ?
thanks
No, we don't always have 3 same outputs with a GHZ state. GHZ state is only HHH + VVV on a given direction. You can just try out a simple transformation to a specific other direction (like L/R instead of H/V) to see this:Heidi said:Have we always 3 same outputs ,with a GHZ state, when we measure the same thing on the particles? linear polarization along a same direction, or same circular polarization?
or is GHZ HHH + VVV state on a given direction?
Here is the free version:Heidi said:could you write the formulas of this article (with some comments)
the price of the article is too expensive (32 dollars)
A GHZ (Greenberger-Horne-Zeilinger) experiment is a type of quantum entanglement experiment where three or more particles are entangled in such a way that their measurement outcomes are highly correlated. This type of experiment is used to test the principles of quantum mechanics and explore the nature of reality at the microscopic level.
In a GHZ experiment, three or more particles are prepared in a specific quantum state and then separated. Each particle is then measured along a specific axis, and the measurement outcomes are compared. If the particles are truly entangled, their measurement outcomes will be highly correlated, even if they are measured at a great distance from each other.
A GHZ experiment is significant because it provides evidence for the principles of quantum mechanics, which have been shown to accurately describe the behavior of particles at the microscopic level. It also has implications for technologies such as quantum computing and cryptography.
One of the main challenges of conducting a GHZ experiment is maintaining the entanglement of the particles over a long distance. This requires precise control and isolation of the particles from external influences. Another challenge is ensuring that the particles are truly entangled and not just correlated through some other means.
While GHZ experiments may seem abstract and disconnected from everyday life, they have practical applications in technologies such as quantum computing and cryptography. These technologies have the potential to greatly impact fields such as data security, communication, and scientific research.