English

Gaps Between Consecutive Primes and the Exponential Distribution

Number Theory 2024-06-14 v2

Abstract

Based on the primes less than 4×10184 \times 10^{18}, Oliveira e Silva et al. (2014) conjectured an asymptotic formula for the sum of the kkth power of the gaps between consecutive primes less than a large number xx. We show that the conjecture of Oliveira e Silva holds if and only if the kkth moment of the first nn gaps is asymptotic to the kkth moment of an exponential distribution with mean logn\log n, though the distribution of gaps is not exponential. Asymptotically exponential moments imply that the gaps asymptotically obey Taylor's law of fluctuation scaling: variance of the first nn gaps \sim (mean of the first nn gaps)2^2. If the distribution of the first nn gaps is asymptotically exponential with mean logn\log n, then the expectation of the largest of the first nn gaps is asymptotic to (logn)2(\log n)^2. The largest of the first nn gaps is asymptotic to (logn)2(\log n)^2 if and only if the Cram\'er-Shanks conjecture holds. Numerical counts of gaps and the maximal gap GnG_n among the first nn gaps test these results. While most values of GnG_n are better approximated by (logn)2(\log n)^2 than by other models, seven values of nn with Gn>2eγ(logn)2G_{n} >2 e^{-\gamma}(\log n)^2 suggest that lim supnGn/[2eγ(logn)2]\limsup_{n \to\infty} G_n/[2e^{-\gamma}(\log n)^2] may exceed 1.

Keywords

Cite

@article{arxiv.2405.16019,
  title  = {Gaps Between Consecutive Primes and the Exponential Distribution},
  author = {Joel E. Cohen},
  journal= {arXiv preprint arXiv:2405.16019},
  year   = {2024}
}

Comments

19 pages, 2 figures, 2 tables; accepted 2024-05-24 for publication in Experimental Mathematics

R2 v1 2026-06-28T16:39:47.847Z