Taxonomy of Three-Qubit Mermin Pentagrams

Metod Saniga; Frédéric Holweck; Hamza Jaffali

doi:10.3390/sym12040534

Taxonomy of Three-Qubit Mermin Pentagrams

Symmetry ◽

10.3390/sym12040534 ◽

2020 ◽

Vol 12 (4) ◽

pp. 534

Author(s):

Metod Saniga ◽

Frédéric Holweck ◽

Hamza Jaffali

Keyword(s):

Polar Space ◽

Fano Plane

Given the fact that the three-qubit symplectic polar space features three different kinds of observables and each of its labeled Fano planes acquires a definite sign, we found that there are 45 distinct types of Mermin pentagrams in this space. A key element of our classification is the fact that any context of such pentagram is associated with a unique (positive or negative) Fano plane. Several intriguing relations between the character of pentagrams’ three-qubit observables and ‘valuedness’ of associated Fano planes are pointed out. In particular, we find two distinct kinds of negative contexts and as many as four positive ones.

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Veldkamp spaces: From (Dynkin) diagrams to (Pauli) groups

International Journal of Geometric Methods in Modern Physics ◽

10.1142/s0219887817500803 ◽

2017 ◽

Vol 14 (05) ◽

pp. 1750080

Author(s):

Metod Saniga ◽

Frédéric Holweck ◽

Petr Pracna

Keyword(s):

Incidence Structure ◽

Polar Space ◽

Exceptional Point ◽

Specific Point ◽

Fano Plane ◽

Magic Square ◽

Dynkin Diagrams ◽

Pauli Matrix ◽

Matrix Formula ◽

Point Line

Regarding a Dynkin diagram as a specific point-line incidence structure (where each line has just two points), one can associate with it a Veldkamp space. Focusing on extended Dynkin diagrams of type [Formula: see text], [Formula: see text], it is shown that the corresponding Veldkamp space always contains a distinguished copy of the projective space PG[Formula: see text]. Proper labeling of the vertices of the diagram (for [Formula: see text]) by particular elements of the two-qubit Pauli group establishes a bijection between the 15 elements of the group and the 15 points of the PG[Formula: see text]. The bijection is such that the product of three elements lying on the same line is the identity and one also readily singles out that particular copy of the symplectic polar space [Formula: see text] of the PG[Formula: see text] whose lines correspond to triples of mutually commuting elements of the group; in the latter case, in addition, we arrive at a unique copy of the Mermin–Peres magic square. In the case of [Formula: see text], a more natural labeling is that in terms of elements of the three-qubit Pauli group, furnishing a bijection between the 63 elements of the group and the 63 points of PG[Formula: see text], the latter being the maximum projective subspace of the corresponding Veldkamp space; here, the points of the distinguished PG[Formula: see text] are in a bijection with the elements of a two-qubit subgroup of the three-qubit Pauli group, yielding a three-qubit version of the Mermin–Peres square. Moreover, save for [Formula: see text], each Veldkamp space is also endowed with some exceptional point(s). Interestingly, two such points in the [Formula: see text] case define a unique Fano plane whose inherited three-qubit labels feature solely the Pauli matrix [Formula: see text].

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A plastically bendable and polar organic crystal

CrystEngComm ◽

10.1039/d1ce00724f ◽

2021 ◽

Author(s):

Sotaro Kusumoto ◽

Akira Sugimoto ◽

Daisuke Kosumi ◽

Yang Kim ◽

Yoshihiro Sekine ◽

...

Keyword(s):

Mechanical Stress ◽

Polar Space ◽

Organic Crystal ◽

Space Group ◽

High Dielectric

In this communication, an organic crystal of the polar space group Pc that is capable of plastically bending in response to external mechanical stress is reported, and its high dielectric...

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