English

Quantum version of the Euler's problem: a geometric perspective

Quantum Physics 2022-12-26 v2

Abstract

The classical combinatorial problem of 3636 officers has no solution, as there are no Graeco-Latin squares of order six. The situation changes if one works in a quantum setup and allows for superpositions of classical objects and admits entangled states. We analyze the recently found solution to the quantum version of the Euler's problem from a geometric point of view. The notion of a non-displaceable manifold embedded in a larger space is recalled. This property implies that any two copies of such a manifold, like two great circles on a sphere, do intersect. Existence of a quantum Graeco-Latin square of size six, equivalent to a maximally entangled state of four subsystems with d=6 levels each, implies that three copies of the manifold U(36)/U(1) of maximally entangled states of the 36×3636\times 36 system, embedded in the complex projective space CP36×361{C}P^{36\times 36 -1}, do intersect simultaneously at a certain point.

Keywords

Cite

@article{arxiv.2212.03903,
  title  = {Quantum version of the Euler's problem: a geometric perspective},
  author = {Karol Zyczkowski},
  journal= {arXiv preprint arXiv:2212.03903},
  year   = {2022}
}

Comments

15 pages with 9 figures, additional references added

R2 v1 2026-06-28T07:25:11.389Z