A Disk-Growth Remez Principle and a Modular Proof of the Measurable Turán-Nazarov Inequality

Abstract

We give a modular proof of the measurable Turán-Nazarov inequality for exponential polynomials. The proof first establishes a Remez principle for holomorphic functions satisfying two disk-growth assumptions. The global growth assumption controls the number of relevant zeros, while the local growth assumption gives an effective degree. This yields Cartan coverings, sublevel estimates, and a geometric-mean Remez inequality. For exponential polynomials with bounded spectral diameter, the required disk growth follows from the classical interval Turán inequality. For large spectral diameter, we use a first-order pruning step. If ρ= ( p) and a∈ p, then Qa = ρ-1(D-a)p has one fewer exponential term, and the quotient Qa/p satisfies an absolute weak distribution estimate away from the zero set of p. Writing Qa = ρ-1(D-a)p, Qb = ρ-1(D-b)p for two farthest spectral points a,b gives Qa-Qb = b-aρp, |b-a| = ρ, and hence |p| |Qa|+|Qb|. The induction is carried out in geometric-mean form on the original measurable set. This avoids losing a fixed proportion of the set at each step and gives the classical measurable Turán-Nazarov inequality with the sharp algebraic exponent m-1. The final measurable L∞ estimate is classical; the point here is the modular proof and the geometric-mean induction. The only Turán-type input is the classical interval Turán inequality.