Abstract
In a recent paper, E. Steingrímsson associated to each simple graph G a simplicial complex Δ G , referred to as the coloring complex of G. Certain nonfaces of Δ G correspond in a natural manner to proper colorings of G. Indeed, the h-vector is an affine transformation of the chromatic polynomial χ G of G, and the reduced Euler characteristic is, up to sign, equal to |χ G (−1)|−1. We show that Δ G is constructible and hence Cohen-Macaulay. Moreover, we introduce two subcomplexes of the coloring complex, referred to as polar coloring complexes. The h-vectors of these complexes are again affine transformations of χ G , and their Euler characteristics coincide with χ′ G (0) and −χ′ G (1), respectively. We show for a large class of graphs—including all connected graphs—that polar coloring complexes are constructible. Finally, the coloring complex and its polar subcomplexes being Cohen-Macaulay allows for topological interpretations of certain positivity results about the chromatic polynomial due to N. Linial and I. M. Gessel.
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Research financed by EC’s IHRP Programme, within the Research Training Network “Algebraic Combinatorics in Europe,” grant HPRN-CT-2001-00272.
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Jonsson, J. The Topology of the Coloring Complex. J Algebr Comb 21, 311–329 (2005). https://doi.org/10.1007/s10801-005-6914-0
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DOI: https://doi.org/10.1007/s10801-005-6914-0