The Fyodorov--Hiary--Keating Conjecture on Mesoscopic Intervals

Abstract

We derive precise upper bounds for the maximum of the Riemann zeta function on a typical short interval of the critical line. We show that for fixed θ∈(-1,0], large T, and y≥ 2 satisfying y=O( T/ T), the proportion of points t∈ [T,2T] for which align* |h|≤ θT|ζ(&12+it+ih)|>ey · eS( T)|θ|/2( T)(1+θ)( T)3/4 align* is bounded above by a constant times y(-2y-y2/((1+θ) T)), where S=S(t) is a quantity whose value distribution is approximately that of a standard Gaussian. Up to a multiplicative constant, this settles the upper bound of a conjecture of Fyodorov--Hiary--Keating which was only known in the leading order for θ∈(-1,0). Using similar techniques, we also derive upper bounds for the second moment of the zeta function on such intervals. We show that for large T, the proportion of t∈ [T,2T] for which align* 1θT∫-θT^θT |ζ(&12+it+ih)|2dh > A eS2|θ| T ( T)(1+θ) T align* tends to zero as A∞, for the same S as above. This proves a weak form of another conjecture of Fyodorov--Keating and generalizes a result of Harper, which is recovered at θ= 0 (in which case S is defined to be zero). Our proofs use an adaptation of the recursive scheme introduced by one of the authors, Bourgade and Radziwiłł.