Determining optimal test functions for 2-level densities

Abstract

Katz and Sarnak conjectured a correspondence between the n-level density statistics of zeros from families of L-functions with eigenvalues from random matrix ensembles. In many cases the sums of smooth test functions, whose Fourier transforms are finitely supported, over scaled zeros in a family converge to an integral of the test function against a density Wn, G depending on the symmetry G of the family (unitary, symplectic or orthogonal). This integral bounds the average order of vanishing at the central point of the corresponding family of L-functions. We can obtain better estimates on this vanishing by finding better test functions to minimize the integral. We pursue this problem when n=2, minimizing \[ 1(0, 0) ∫ R2 W2,G (x, y) (x, y) dx dy \] over test functions R2 [0, ∞) with compactly supported Fourier transform. We study a restricted version of this optimization problem, imposing that our test functions take the form φ(x) (y) for some fixed admissible (y) and supp( φ) ⊂eq [-1, 1]. Extending results from the 1-level case, namely the functional analytic arguments of Iwaniec, Luo and Sarnak and the differential equations method introduced by Freeman and Miller, we explicitly solve for the optimal φ for appropriately chosen fixed test function . The solution allows us to deduce strong estimates for the proportion of newforms of rank 0 or 2 in the case of SO(even), rank 1 or 3 in the case of SO(odd), and rank at most 2 for O, Sp, and U; our estimates are a significant strengthening of the best known estimates obtained with the 1-level density. We conclude by discussing further improvements on estimates by the method of iteration.