English

Bounds and Conjectures for additive divisor sums

Number Theory 2017-05-19 v2

Abstract

Additive divisor sums play a prominent role in the theory of the moments of the Riemann zeta function. There is a long history of determining sharp asymptotic formula for the shifted convolution sum of the ordinary divisor function. In recent years, it has emerged that a sharp asymptotic formula for the shifted convolution sum of the triple divisor function would be useful in evaluating the sixth moment of the Riemann zeta function. In this article, we study Dk,(x)=nxτk(n)τ(n+h)D_{k,\ell}(x) = \sum_{n \le x} \tau_k(n) \tau_{\ell}(n+h) where τk\tau_k and τ\tau_{\ell} are the kk-th and \ell-th divisor functions. The main result is a lower bound of the correct order of magnitude for Dk,(x,h)D_{k,\ell}(x,h), uniform in hh. In addition, the conjectural asymptotic formula for Dk,(x,h)D_{k,\ell}(x,h) is studied. Using an argument of Ivi\'{c} and Conrey-Gonek the leading term in the conjectural asymptotic formula is simplified. In addition, a probabilistic method is presented which gives the same leading term. Finally, we show that these two methods give the same answer as in a recent probabilistic argument of Terry Tao.

Keywords

Cite

@article{arxiv.1609.01411,
  title  = {Bounds and Conjectures for additive divisor sums},
  author = {Nathan Ng and Mark Thom},
  journal= {arXiv preprint arXiv:1609.01411},
  year   = {2017}
}

Comments

This is the second version of the article. The article now considers the more general sums $D_{k,\ell}(x,h) = \sum_{n \le x} \tau_k(n) \tau_{\ell}(n+h)$. We also show that our probabilistic argument and Terry Tao's probabilistic argument give the same conjecture for $D_{k,\ell}(x,h)$

R2 v1 2026-06-22T15:40:49.630Z