Quantum ergodicity for shrinking balls in arithmetic hyperbolic manifolds

Abstract

We study a refinement of the quantum unique ergodicity conjecture for shrinking balls on arithmetic hyperbolic manifolds, with a focus on dimensions 2 and 3 . For the Eisenstein series for the modular surface PSL2( Z) H2 we prove failure of quantum unique ergodicity close to the Planck-scale and an improved bound for its quantum variance. For arithmetic 3 -manifolds we show that quantum unique ergodicity of Hecke-Maa forms fails on shrinking balls centered on an arithmetic point and radius R tj-δ with δ > 3/4 . For PSL2(OK) H3 with OK being the ring of integers of an imaginary quadratic number field of class number one, we prove, conditionally on the generalized Lindel\"of hypothesis, that equidistribution holds for Hecke-Maass forms if δ < 2/5 . Furthermore, we prove that equidistribution holds unconditionally for the Eisenstein series if δ < (1-2θ)/(34+4θ) where θ is the exponent towards the Ramanujan-Petersson conjecture. For PSL2(Z[i]) we improve the last exponent to δ < (1-2θ)/(27+2θ) . Studying mean Lindel\"of estimates for L -functions of Hecke-Maa forms we improve the last exponent on average to δ < 2/5. Finally, we study massive irregularities for Laplace eigenfunctions on n -dimensional compact arithmetic hyperbolic manifolds for n ≥ 4 . We observe that quantum unique ergodicity fails on shrinking balls of radii R t-δn+ε away from the Planck-scale, with δn = 5/(n+1) for n ≥ 5 .