A near-quadratic lower bound on the border determinantal complexity of Σi xin via conormal specialization

Abstract

The border determinantal complexity (f) of a polynomial f is the least m such that f is a limit of determinants of m× m matrices of affine-linear forms. We prove that for every n3, over , \[ (Σi=1n xin)\ \ (n-1)24e, (Σi=1n xin)\ \ (n-1)22e \] in the ordinary and symmetric models respectively; both match the known O(n2) upper bounds up to the constant. To our knowledge these are the first border determinantal lower bounds for an explicit family that are superlinear in the number of variables: the known quadratic border bound for the permanent reads the dimension of the dual variety and is linear in its number of variables, whereas we transfer the dual degree. The proof has two ingredients. The first is an unconditional bound on the slot-(n-2) conormal multidegree of the multiplicity-one Gauss-graph cycle of an arbitrary affine-linear determinant -- singular, reducible, and non-reduced fibers allowed -- by a multihomogeneous Bézout count of a lifted kernel incidence. The second is a specialization argument: along any degeneration AcΣixin, the flat limit of these Gauss-graph cycles contains the conormal variety of the Fermat cone with positive coefficient. A cone-shift identity converts that conormal multidegree into the classical dual degree n(n-1)n-2 of the smooth Fermat hypersurface, and an (n-1)-st root yields the quadratic bound. The exact lower bounds of the author's companion manuscripts follow as corollaries.