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Truong Pham.  Ψ: state of a particle  Φ: state of a measuring device  Ψ(+) : state of a particle that has an upspin  Ψ(-): state of a particle.

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Presentation on theme: "Truong Pham.  Ψ: state of a particle  Φ: state of a measuring device  Ψ(+) : state of a particle that has an upspin  Ψ(-): state of a particle."— Presentation transcript:

1 Truong Pham

2

3

4

5  Ψ: state of a particle  Φ: state of a measuring device  Ψ(+) : state of a particle that has an upspin  Ψ(-): state of a particle that has a downspin  Φ(+): state of a measuring device corresponding to an upspin  Φ(-): state of a measuring device corresponding to a downspin

6  At t= 0:  Ψo=mΨ(+)+nΨ(-), m^2+n^2=1  P=Ψo* Φo=(mΨ(+)+nΨ(-))* Φo  As t -> ∞:  P=mΨ(+)* Φ(+)+nΨ(-) Φ(-)

7  Born: the possibility of getting upspin and downspin is m^2 and n^2, respectively  Heisenberg: the state of the total system is a superposition between the upspin and the downspin states. Once observation is made, the system is collapsed to one state

8

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10  P=mΨ(live)* Φ(atom)+nΨ(dead) Φ(decay)  Born: probabilities for the kitty to be alive and dead are m^2 and n^2, respectively.  Heisenberg: the kitty is in a superposition of dead and alive states before one opens the box  Einstein: “Both points of view are logically unobjectionable; but I cannot believe that either of these viewpoints will finally be established.” (Cushing, 312)

11  1. Born is right -> incompleteness of QM.  2. Heisenberg is right -> the cat’s actual physical state before observation is actually a superposition of death and life -> the mere act of observing either kills or let the cat live on  2 does not sound right (Or does it?).  Therefore 1: QM is an incomplete theory.

12 SPOOKY!

13  EPR paper was coauthored by Einstein, Podolsky and Rosen.  Modified by David Bohm  Basis for hidden variables theory: Distant events cannot have instantaneous effect on local ones.

14 P=mΨ(+)* Φ(+)+nΨ(-) Φ(-)

15  If particle 1’s spin is observed to be up, particle 2 has to have a downspin.  Vice versa  Merely observing 1 particle changes the state of the other.  Two particles can be infinitely far away from each other  -> Information travels faster than light?

16  A set of inequalities to prove that in some cases, local hidden variables theory cannot be satisfied  Verified by experiment that entanglement does indeed happen  But does information actually travels faster than light in violation of general relativity?

17  No  If we consider 2 particles as a system  The overall wave function for the system collapses when we make an observation  Just like the Schrodinger’s cat  No information transmission takes place

18  Na ah,  Non-local hidden-variables theory

19  Speed of information transmission was measured to be at least 10,000 times greater than the speed of light!  Quantum computing

20  Which interpretation is realist? Or is Quantum Mechanics essentially instrumentalist?  Einstein and Bohn’s conversation: E: Do you realistically believe that the Moon does not exist if nobody is looking at it? B: You cannot disprove that…

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