On the Word-Representability of 5-Regular Circulant Graphs

Abstract

A graph G = (V, E) is word-representable if there exists a word w over the alphabet V such that, for any two distinct vertices x, y ∈ V, xy ∈ E if and only if x and y alternate in w. Two letters x and y are said to alternate in w if, after removing all other letters from w, the resulting word is of the form xyxy… or yxyx… (of even or odd length). For a given set R = \r1, r2, …, rk\ of jump elements, an undirected circulant graph Cn(R) on n vertices has vertex set \0, 1, …, n-1\ and edge set E = \ \i,j\ \;|\; |i - j| n ∈ \r1, r2, …, rk\ \, where 0 < r1 < r2 < … < rk < n2. Recently, Kitaev and Pyatkin proved that every 4-regular circulant graph is word-representable. Srinivasan and Hariharasubramanian further investigated circulant graphs and obtained bounds on the representation number for k-regular circulant graphs with 2 k 4. In addition to these positive results, their work also presents examples of non-word-representable circulant graphs. In this work, we study word-representability and the representation number of 5-regular circulant graphs via techniques from elementary number theory and group theory, as well as graph coloring, graph factorization and morphisms.

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