Low lying zeros of Rankin-Selberg L-functions

Abstract

We study the low lying zeros of GL(2) × GL(2) Rankin-Selberg L-functions. Assuming the generalized Riemann hypothesis, we compute the 1-level density of the low-lying zeroes of L(s, f g) averaged over families of Rankin-Selberg convolutions, where f, g are cuspidal newforms with even weights k1, k2 and prime levels N1, N2, respectively. The Katz-Sarnak density conjecture predicts that in the limit, the 1-level density of suitable families of L-functions is the same as the distribution of eigenvalues of corresponding families of random matrices. The 1-level density relies on a smooth test function φ whose Fourier transform φ has compact support. In general, we show the Katz-Sarnak density conjecture holds for test functions φ with supp φ ⊂ (-12, 12). When N1 = N2, we prove the density conjecture for supp φ ⊂ (-54, 54) when k1 k2, and supp φ ⊂ (-2928, 2928) when k1 = k2. A lower order term emerges when the support of φ exceeds (-1, 1), which makes these results particularly interesting. The main idea which allows us to extend the support of φ beyond (-1, 1) is an analysis of the products of Kloosterman sums arising from the Petersson formula. We also carefully treat the contributions from poles in the case where k1 = k2. Our work provides conditional lower bounds for the proportion of Rankin-Selberg L-functions which are non-vanishing at the central point and for a related conjecture of Keating and Snaith on central L-values.