A Variation Norm Carleson Theorem Along the Primes
Abstract
Let Λ denote the von Mangoldt function; we prove that for each r > 2, there exist constants \[ r' < c(r) < 2 < C(r), r ∞ c(r) = 1, \ r ∞ C(r) = ∞ \] so that the discrete variational Carleson operator along the primes align Vr ( Σn ≠ 0 f(x-n) Λ(|n|) e2πi λnn : λ∈ T ) align is bounded on p for all c(r) < p < C(r), while the variation is unbounded when p ≤ r'. At the non-variational endpoint, the same argument gives the sharp maximal result: the prime Carleson operator \[ λ∈ T |Σn≠0 f(x-n)Λ(|n|)e2πiλnn| \] is bounded on \(p( Z)\) for the full expected range \(1<p<∞\). The proof gives a new mechanism for treating modulation-invariant singular integrals after arithmetic sparsification. It combines higher-order Fourier uniformity, a variable-coefficient multi-frequency principle in the spirit of Bourgain, and an additive-combinatorial inverse argument. A key step is a reduction to finite periodic models, where the Ramanujan structure of the major arcs is converted into a sharp estimate for structured atoms by elementary number theory.
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