The complexity of the fermionant, and immanants of constant width

Abstract

In the context of statistical physics, Chandrasekharan and Wiese recently introduced the fermionant k, a determinant-like quantity where each permutation π is weighted by -k raised to the number of cycles in π. We show that computing k is #P-hard under Turing reductions for any constant k > 2, and is -hard for k=2, even for the adjacency matrices of planar graphs. As a consequence, unless the polynomial hierarchy collapses, it is impossible to compute the immanant λ \,A as a function of the Young diagram λ in polynomial time, even if the width of λ is restricted to be at most 2. In particular, if 2 is in P, or if λ is in P for all λ of width 2, then ⊂eq and there are randomized polynomial-time algorithms for NP-complete problems.