Quantum Computer Simulation of GHZ Experiment

​
quantum computer
Mermin GHZ
detector configuration
GHZ
XXX
XYY
YXY
YYX
local realism "presets"
111
100
010
001
An entangled state of three photons in a superposition, either with all horizontally polarized (
HHH
) or with all vertically polarized (
VVV
), is known as a Greenberger–Horne–Zeilinger (GHZ) state[1, 2]. It is represented by the state vector
Ψ=
1
2
(HHH〉+VVV〉)
. A measurement on any one of the photons, using a two-channel polarizer, would give 50% probability for either
H
or
V
. Measurements on the other two photons would then be found to show the same polarization. In the canonical GHZ experiment, measurements are performed on the three entangled photons using two-channel polarizers
D1
,
D2
and
D3
set to orientations different from the original
H
and
V
, which we denote by
X
and
Y
. The
X
polarizations are at angles of
±45°
with respect to the original polarizations, such that
X=
1
2
(H〉±V〉)
. The
Y
polarizations are left and right circular polarizations, represented by
Y=
1
2
(H〉±iV〉)
. The polarization detectors are set in one of four possible combinations:
XXX
,
XYY
,
YXY
or
YYX
. We use binary notation, 0 and 1, to label the two possible polarizations for either the
X
or
Y
orientation. For the
XYY
,
YXY
or
YYX
configuration, we observe four equally probable results, which we designate 001, 010, 001 and 111. For
XXX
, we again observe four equally probable results, but now 000, 011, 101 or 110. In all of these cases, any two detector readings, say those of
D1
and
D2
, unambiguously determine the reading of
D3
. For example, for configuration
XYY
, if the first two detectors read 01 or 10, the third would then show 0.
In this Demonstration, a GHZ experiment is simulated using a three-qubit quantum computer[3]. The GHZ state
Ψ=
1
2
(000〉+111〉)
is produced by a circuit using one Hadamard (
H
) and two CNOT gates. The polarization detectors are simulated by a combination of
H
and
S
gates. The output state, for example,
Ψ=
1
2
(001〉+010〉+100〉+111〉)
, implies that the final bit measurements give the results 001, 010, 100 and 111 with equal probability. Also shown is an illustration of Mermin's Gedankenexperiment[4], which is a simplification of the actual GHZ experiment. The results shown are those corresponding to local realism, with the selected "presets," which can be compared with the quantum-mechanics results.
The results of all reproducible experiments agree with the predictions of quantum mechanics and are contrary to those of local realism, which would entail the existence of hidden variables. According to local realism, each photon would be presumed to carry an "instruction set" that determines, in advance, its polarization in any
X
or
Y
measurement. The result that any two readings unambiguously determine the third itself negates the possibility of local realism, since the third photon cannot "communicate" with the other two once they leave the source. The failure of local realism is shown in the references, using more tediously detailed arguments. In contrast to Bell's inequalities, in which this conclusion is reached by statistical analysis of a multitude of experimental results, the GHZ experiment requires only a single run.

Details

The Hadamard gate
H
(not to be confused with the horizontal polarization, also called
H
) acts on a qubit in one of the basis states to produce a linear combination of the two basis states. Specifically
H0=
1
2
(0〉+1〉)
and
H1=
1
2
(0〉-1〉)
. As a unitary operator,
H=
1
2

1
1
1
-1

. The
π/2
-phase shift gate
S
is represented by
S=
1
0
0
i

.

References

[1] D. M. Greenberger, M. A. Horne, A. Shimony and A. Zeilinger, "Bell's Theorem without Inequalities," American Journal of Physics, 58(12), 1990 pp. 1131–1143. doi:10.1119/1.16243.
[2] J.-W. Pan, D. Bouwmeester, M. Daniell, H. Weinfurter and A. Zeilinger, "Experimental Test of Quantum Nonlocality in Three-Photon Greenberger–Horne–Zeilinger Entanglement," Nature, 403, 2000 pp. 515–519. doi:10.1038/35000514.
[3] G. Fano and S. M. Blinder, Twenty-First Century Quantum Mechanics: Hilbert Space to Quantum Computers, New York: Springer, 2017.
[4] N. D. Mermin, "Quantum Mysteries Revisited," American Journal of Physics, 58(8), 1990 pp. 731–734. doi:10.1119/1.16503.

External Links

Gedankenexperiment for Three Entangled Electrons: Analog of GHZ Photon Experiments
Stern-Gerlach Simulations on a Quantum Computer

Permanent Citation

S. M. Blinder
​
​"Quantum Computer Simulation of GHZ Experiment"​
​http://demonstrations.wolfram.com/QuantumComputerSimulationOfGHZExperiment/​
​Wolfram Demonstrations Project​
​Published: December 18, 2017