Eigenvalue bounds for the quantum chromatic number of graph powers
Abstract
The quantum chromatic number, a generalization of the chromatic number, was first defined in relation to the non-local quantum coloring game. We generalize the former by defining the quantum k-distance chromatic number kq(G) of a graph G, which can be seen as the quantum chromatic number of the k-th power graph, Gk, and as generalization of the classical k-distance chromatic number k(G) of a graph. It can easily be shown that kq(G) ≤ k(G). In this paper, we strengthen three classical eigenvalue bounds for the k-distance chromatic number by showing they also hold for the quantum counterpart of this parameter. This shows that several bounds by Elphick et al. [J. Combinatorial Theory Ser. A 168, 2019, Electron. J. Comb. 27(4), 2020] hold in the more general setting of distance-k colorings. As a consequence we obtain several graph classes for which kq(G)=k(G), thus increasing the number of graphs for which the quantum parameter is known.
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