Greenberger–Horne–Zeilinger state

In physics, in the area of quantum information theory, a Greenberger–Horne–Zeilinger state (GHZ state) is a certain type of entangled quantum state that involves at least three subsystems (particle states, qubits, or qudits). The four-particle version was first studied by Daniel Greenberger, Michael Horne and Anton Zeilinger in 1989, and the three-particle version was introduced by N. David Mermin in 1990.^[1]^[2]^[3] Extremely non-classical properties of the state have been observed. GHZ states for large numbers of qubits are theorized to give enhanced performance for metrology compared to other qubit superposition states.^[4]

YouTube Encyclopedic

1/5
Views:
479
1 600 709
1 670
2 103
423

Transcription

Definition

The GHZ state is an entangled quantum state for 3 qubits and its state is

|\mathrm {GHZ} \rangle ={\frac {|000\rangle +|111\rangle }{\sqrt {2}}}.

Generalization

The generalized GHZ state is an entangled quantum state of $M > 2$ subsystems. If each system has dimension $d$ , i.e., the local Hilbert space is isomorphic to $\mathbb {C} ^{d}$ , then the total Hilbert space of an $M$ -partite system is ${\mathcal {H}}_{\rm {tot}}=(\mathbb {C} ^{d})^{\otimes M}$ . This GHZ state is also called an $M$ -partite qudit GHZ state. Its formula as a tensor product is

|\mathrm {GHZ} \rangle ={\frac {1}{\sqrt {d}}}\sum _{i=0}^{d-1}|i\rangle \otimes \cdots \otimes |i\rangle ={\frac {1}{\sqrt {d}}}(|0\rangle \otimes \cdots \otimes |0\rangle +\cdots +|d-1\rangle \otimes \cdots \otimes |d-1\rangle )

In the case of each of the subsystems being two-dimensional, that is for a collection of M qubits, it reads

|\mathrm {GHZ} \rangle ={\frac {|0\rangle ^{\otimes M}+|1\rangle ^{\otimes M}}{\sqrt {2}}}.

Properties

There is no standard measure of multi-partite entanglement because different, not mutually convertible, types of multi-partite entanglement exist. Nonetheless, many measures define the GHZ state to be maximally entangled state.^{[citation needed]}

Another important property of the GHZ state is that taking the partial trace over one of the three systems yields

\operatorname {Tr} _{3}\left[\left({\frac {|000\rangle +|111\rangle }{\sqrt {2}}}\right)\left({\frac {\langle 000|+\langle 111|}{\sqrt {2}}}\right)\right]={\frac {(|00\rangle \langle 00|+|11\rangle \langle 11|)}{2}},

which is an unentangled mixed state. It has certain two-particle (qubit) correlations, but these are of a classical nature. On the other hand, if we were to measure one of the subsystems in such a way that the measurement distinguishes between the states 0 and 1, we will leave behind either $|00\rangle$ or $|11\rangle$ , which are unentangled pure states. This is unlike the W state, which leaves bipartite entanglements even when we measure one of its subsystems.^{[citation needed]}

The GHZ state is non-biseparable^[5] and is the representative of one of the two non-biseparable classes of 3-qubit states which cannot be transformed (not even probabilistically) into each other by local quantum operations, the other being the W state, $|\mathrm {W} \rangle =(|001\rangle +|010\rangle +|100\rangle )/{\sqrt {3}}$ .^[6] Thus $|\mathrm {GHZ} \rangle$ and $|\mathrm {W} \rangle$ represent two very different kinds of entanglement for three or more particles.^[7] The W state is, in a certain sense "less entangled" than the GHZ state; however, that entanglement is, in a sense, more robust against single-particle measurements, in that, for an N-qubit W state, an entangled (N − 1)-qubit state remains after a single-particle measurement. By contrast, certain measurements on the GHZ state collapse it into a mixture or a pure state.

The GHZ state leads to striking non-classical correlations (1989). Particles prepared in this state lead to a version of Bell's theorem, which shows the internal inconsistency of the notion of elements-of-reality introduced in the famous Einstein–Podolsky–Rosen article. The first laboratory observation of GHZ correlations was by the group of Anton Zeilinger (1998), who was awarded a share of the 2022 Nobel Prize in physics for this work.^[8] Many more accurate observations followed. The correlations can be utilized in some quantum information tasks. These include multipartner quantum cryptography (1998) and communication complexity tasks (1997, 2004).

Pairwise entanglement

Although a measurement of the third particle of the GHZ state that distinguishes the two states results in an unentangled pair, a measurement along an orthogonal direction can leave behind a maximally entangled Bell state. This is illustrated below.

The 3-qubit GHZ state can be written as

|\mathrm {GHZ} \rangle ={\frac {1}{\sqrt {2}}}\left(|000\rangle +|111\rangle \right)={\frac {1}{2}}\left(|00\rangle +|11\rangle \right)\otimes |+\rangle +{\frac {1}{2}}\left(|00\rangle -|11\rangle \right)\otimes |-\rangle ,

where the third particle is written as a superposition in the X basis (as opposed to the Z basis) as $|0\rangle =(|+\rangle +|-\rangle )/{\sqrt {2}}$ and $|1\rangle =(|+\rangle -|-\rangle )/{\sqrt {2}}$ .

A measurement of the GHZ state along the X basis for the third particle then yields either $|\Phi ^{+}\rangle =(|00\rangle +|11\rangle )/{\sqrt {2}}$ , if $|+\rangle$ was measured, or $|\Phi ^{-}\rangle =(|00\rangle -|11\rangle )/{\sqrt {2}}$ , if $|-\rangle$ was measured. In the later case, the phase can be rotated by applying a Z quantum gate to give $|\Phi ^{+}\rangle$ , while in the former case, no additional transformations are applied. In either case, the result of the operations is a maximally entangled Bell state.

This example illustrates that, depending on which measurement is made of the GHZ state is more subtle than it first appears: a measurement along an orthogonal direction, followed by a quantum transform that depends on the measurement outcome, can leave behind a maximally entangled state.

Applications

GHZ states are used in several protocols in quantum communication and cryptography, for example, in secret sharing^[9] or in the quantum Byzantine agreement.

References

^ Greenberger, Daniel M.; Horne, Michael A.; Zeilinger, Anton (1989). "Going beyond Bell's Theorem". In Kafatos, M. (ed.). Bell's Theorem, Quantum Theory and Conceptions of the Universe. Dordrecht: Kluwer. p. 69. arXiv:0712.0921. Bibcode:2007arXiv0712.0921G.
^ Mermin, N. David (August 1, 1990). "Quantum mysteries revisited". American Journal of Physics. 58 (8): 731–734. Bibcode:1990AmJPh..58..731M. doi:10.1119/1.16503. ISSN 0002-9505. S2CID 119911419.
^ Caves, Carlton M.; Fuchs, Christopher A.; Schack, Rüdiger (August 20, 2002). "Unknown quantum states: The quantum de Finetti representation". Journal of Mathematical Physics. 43 (9): 4537–4559. arXiv:quant-ph/0104088. Bibcode:2002JMP....43.4537C. doi:10.1063/1.1494475. ISSN 0022-2488. S2CID 17416262. Mermin was the first to point out the interesting properties of this three-system state, following the lead of D. M. Greenberger, M. Horne, and A. Zeilinger [...] where a similar four-system state was proposed.
^ Eldredge, Zachary; Foss-Feig, Michael; Gross, Jonathan A.; Rolston, S. L.; Gorshkov, Alexey V. (April 23, 2018). "Optimal and secure measurement protocols for quantum sensor networks". Physical Review A. 97 (4): 042337. arXiv:1607.04646. Bibcode:2018PhRvA..97d2337E. doi:10.1103/PhysRevA.97.042337. PMC 6513338. PMID 31093589.
^ A pure state $|\psi \rangle$ of $N$ parties is called biseparable, if one can find a partition of the parties in two nonempty disjoint subsets $A$ and $B$ with $A\cup B=\{1,\dots ,N\}$ such that $|\psi \rangle =|\phi \rangle _{A}\otimes |\gamma \rangle _{B}$ , i.e. $|\psi \rangle$ is a product state with respect to the partition $A|B$ .
^ W. Dür; G. Vidal & J. I. Cirac (2000). "Three qubits can be entangled in two inequivalent ways". Phys. Rev. A. 62 (6): 062314. arXiv:quant-ph/0005115. Bibcode:2000PhRvA..62f2314D. doi:10.1103/PhysRevA.62.062314. S2CID 16636159.
^ Piotr Migdał; Javier Rodriguez-Laguna; Maciej Lewenstein (2013), "Entanglement classes of permutation-symmetric qudit states: Symmetric operations suffice", Physical Review A, 88 (1): 012335, arXiv:1305.1506, Bibcode:2013PhRvA..88a2335M, doi:10.1103/PhysRevA.88.012335, S2CID 119536491
^ "Scientific Background on the Nobel Prize in Physics 2022" (PDF). The Nobel Prize. October 4, 2022.
^ Mark Hillery; Vladimír Bužek; André Berthiaume (1998), "Quantum secret sharing", Physical Review A, 59 (3): 1829–1834, arXiv:quant-ph/9806063, Bibcode:1999PhRvA..59.1829H, doi:10.1103/PhysRevA.59.1829, S2CID 55165469

This page was last edited on 27 March 2024, at 21:08

From Wikipedia, the free encyclopedia