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Abstract

Huh-Stevens and Ferroni-Schr\"oter independently conjectured that the Hilbert-Poincar\'e series of the Chow ring of any geometric lattice has only real zeros, and Ferroni, Matherne and the second author extended this conjecture to the Chow polynomial of any Cohen-Macaulay poset. In this paper we address these conjectures by providing new defining relations and properties of Chow functions of posets and matrices. These are used, in conjunction with new techniques on interlacing sequences of polynomials, to prove that the Chow polynomial of any lower triangular and totally nonnegative matrix with all diagonal entries equal to one is real-rooted. This in turn is used to prove the above conjectures for a large class of posets and matroids that includes projective and affine geometries, dual partition and Dowling lattices, perfect matroid designs and paving matroids. A consequence of our theory is a vast generalization of a recent theorem of Athanasiadis on real-rootedness preserving properties of the Eulerian transformation, which was conjectured by the first author and Jochemko. We study Chow polynomials of Toeplitz matrices in greater detail. These turn out to be related to a family of generalized Eulerian polynomials with coefficients in the ring of symmetric polynomials that have been studied frequently in the literature, by e.g. Stanley, Brenti, Stembridge and Shareshian-Wachs. Hence the theory developed in this paper serves as a framework for these polynomials, which are proved to be real-rooted by our methods (when suitably specialized).