Bounds for twisted symmetric square L-functions via half-integral weight periods

Abstract

We establish the first moment bound Σ L( , 12) p5/4+ for triple product L-functions, where is a fixed Hecke-Maass form on SL2(Z) and runs over the Hecke-Maass newforms on 0(p) of bounded eigenvalue. The proof is via the theta correspondence and analysis of periods of half-integral weight modular forms. This estimate is not expected to be optimal, but the exponent 5/4 is the strongest obtained to date for a moment problem of this shape. We show that the expected upper bound follows if one assumes the Ramanujan conjecture in both the integral and half-integral weight cases. Under the triple product formula, our result may be understood as a strong level aspect form of quantum ergodicity: for a large prime p, all but very few Hecke-Maass newforms on 0(p) H of bounded eigenvalue have very uniformly distributed mass after pushforward to SL2(Z) H. Our main result turns out to be closely related to estimates such as Σ|n| < p L( n p,12) p, where the sum is over n for which n p is a fundamental discriminant and n p denotes the corresponding quadratic character. Such estimates improve upon bounds of Duke-Iwaniec.