English

Maass forms and the mock theta function $f(q)$

Number Theory 2019-03-11 v2

Abstract

Let f(q)=1+n=1α(n)qnf(q)=1+\sum_{n=1}^{\infty} \alpha(n)q^n be the well-known third order mock theta of Ramanujan. In 1964, George Andrews proved an asymptotic formula of the form α(n)=cnψ(n)+Oϵ(nϵ),\alpha(n)= \sum_{c\leq\sqrt{n}} \psi(n)+O_\epsilon\left(n^\epsilon\right), where ψ(n)\psi(n) is an expression involving generalized Kloosterman sums and the II-Bessel function. Andrews conjectured that the series converges to α(n)\alpha(n) when extended to infinity, and that it does not converge absolutely. Bringmann and Ono proved the first of these conjectures. Here we obtain a power savings bound for the error in Andrews' formula, and we also prove the second of these conjectures. Our methods depend on the spectral theory of Maass forms of half-integral weight, and in particular on an average estimate which we derive for the Fourier coefficients of such forms which gives a power savings in the spectral parameter. As a further application of this result, we derive a formula which expresses α(n)\alpha(n) with small error as a sum of exponential terms over imaginary quadratic points (this is similar in spirit to a recent result of Masri). We also obtain a bound for the size of the error term incurred by truncating Rademacher's analytic formula for the ordinary partition function which improves a result of the first author and Andersen when 24n2324n-23 is squarefree.

Keywords

Cite

@article{arxiv.1806.01187,
  title  = {Maass forms and the mock theta function $f(q)$},
  author = {Scott Ahlgren and Alexander Dunn},
  journal= {arXiv preprint arXiv:1806.01187},
  year   = {2019}
}

Comments

31 pages. Added remarks in Section 4, fixed several typos

R2 v1 2026-06-23T02:18:23.095Z