Fluxes, Laplacians and Kasteleyn's Theorem

Abstract

The following problem, which stems from the ``flux phase'' problem in condensed matter physics, is analyzed and extended here: One is given a planar graph (or lattice) with prescribed vertices, edges and a weight txy on each edge (x,y). The flux phase problem (which we partially solve) is to find the real phase function on the edges, θ(x,y), so that the matrix T:=\ txy exp[iθ(x,y)]\ minimizes the sum of the negative eigenvalues of -T. One extension of this problem which is also partially solved is the analogous question for the Falicov-Kimball model. There one replaces the matrix -T by -T+V, where V is a diagonal matrix representing a potential. Another extension of this problem, which we solve completely for planar, bipartite graphs, is to maximize det\ T . Our analysis of this determinant problem is closely connected with Kasteleyn's 1961 theorem (for arbitrary planar graphs) and, indeed, yields an alternate, and we believe more transparent proof of it. .

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