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EXPLICIT ESTIMATES FOR THE DISTRIBUTION OF PRIMES

Part of: Multiplicative number theory Zeta and $L$-functions: analytic theory

Published online by Cambridge University Press:  22 June 2023

MICHAELA CULLY-HUGILL Open the ORCID record for MICHAELA CULLY-HUGILL [Opens in a new window]
MICHAELA CULLY-HUGILL*
Affiliation:
School of Science, University of New South Wales Canberra, Canberra ACT 2612, Australia
*
e-mail: m.cully-hugill@adfa.edu.au
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Abstract

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Keywords

distribution of primesprimes in intervalsprime number theoremRiemann–von Mangoldt explicit formulaRiemann zeta function

MSC classification

Primary: 11N05: Distribution of primes
Secondary: 11M06: $zeta (s)$ and $L(s, chi)$ 11M26: Nonreal zeros of $zeta (s)$ and $L(s, chi)$; Riemann and other hypotheses 11N37: Asymptotic results on arithmetic functions
Type
PhD Abstract
Information
Bulletin of the Australian Mathematical Society , Volume 108 , Issue 2 , October 2023 , pp. 341 - 342
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Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of Australian Mathematical Publishing Association Inc.

This thesis presents new explicit results on the distribution of prime numbers. The results largely fall into the categories of error estimates for the prime number theorem (PNT) and interval estimates for primes. The error in the PNT can be estimated with the truncated Riemann–von Mangoldt explicit formula

$$ \begin{align*}\psi(x) = x- \sum_{|\gamma|\le T} \frac{x^\rho}{\rho} + E(x,T),\end{align*} $$

where $\rho = \beta +i\gamma $ represents the nontrivial zeros of the Riemann zeta-function. A new explicit version of Goldston’s estimate for $E(x,T)$ is proved, of order

$$ \begin{align*}E(x,T) = O\bigg(\frac{x\log x\log\log x}{T}\bigg).\end{align*} $$

This estimate is used to update two short-interval results: we prove that there are primes between cubes, that is, in intervals $(n^3, (n + 1)^3)$ for all $n \ge \exp (\exp (32.537))$ , and primes between $n^{155}$ and $(n + 1)^{155}$ for all $n \ge 1$ . These results are published in [Reference Cully-Hugill1]. The proof follows the original method of Ingham and builds on work of Dudek [Reference Dudek6]. We also use, and prove, updated versions of Bertrand’s postulate of primes in $(n, 2n - 2)$ for integers $n> 3$ . This work is published in [Reference Cully-Hugill and Lee4], with corrections in [Reference Cully-Hugill and Lee5]. The methods of Ramaré and Saouter [Reference Ramaré and Saouter8] and Kadiri and Lumley [Reference Kadiri and Lumley7] are used to give new pairs $(\Delta , x_0)$ for which there exist at least one prime in $((1 - \Delta ^{-1})x, x]$ for all $x \ge x_0$ . For instance, we can take $(x_0, \Delta ) = (e^{150}, 2.07 \times 10^{11})$ . Lastly, new conditional results are proved for the error in the PNT. Under the Riemann hypothesis (RH), we prove an explicit error estimate and an explicit mean-value estimate for the PNT in short intervals. The former is published in [Reference Cully-Hugill and Dudek2] and the latter is in the preprint [Reference Cully-Hugill and Dudek3]. The mean-value estimate is based on Selberg’s work [Reference Selberg9], and is of particular interest for its applications, of which two are given. We first prove that under the RH, there is a prime in $(y,y + 37\log ^2 y]$ for at least half the $y \in [x,2x]$ and all $x \ge 2$ . The second application is to Goldbach numbers: we prove that under the RH, there is a Goldbach number in $(x, x + 864 \log ^2 x]$ for all $x \ge 2$ .

Footnotes

Thesis submitted to the University of New South Wales in March 2023; degree approved on 12 May 2023; primary supervisor Timothy Trudgian, secondary supervisor Harvinder Sidhu.

References

Cully-Hugill, M., ‘Primes between consecutive powers,’ J. Number Theory 247 (2023), 100117.10.1016/j.jnt.2022.12.002CrossRefGoogle Scholar
Cully-Hugill, M. and Dudek, A. W., ‘A conditional explicit result for the prime number theorem in short intervals’, Res. Number Theory 8(61) (2022), 18.10.1007/s40993-022-00358-1CrossRefGoogle Scholar
Cully-Hugill, M. and Dudek, A. W., ‘An explicit Selberg mean-value result with applications’, Preprint, 2022, arXiv:2206.00433.Google Scholar
Cully-Hugill, M. and Lee, E. S., ‘Explicit interval estimates for prime numbers’, Math. Comput. 91(336) (2022), 19551970.10.1090/mcom/3719CrossRefGoogle Scholar
Cully-Hugill, M. and Lee, E. S., ‘Explicit interval estimates for prime numbers’, Preprint, 2022, arXiv:2103.05986.10.1090/mcom/3884CrossRefGoogle Scholar
Dudek, A. W., ‘An explicit result for primes between cubes’, Funct. Approx. Comment. Math. 55(2) (2016), 177197.10.7169/facm/2016.55.2.3CrossRefGoogle Scholar
Kadiri, H. and Lumley, A., ‘Short effective intervals containing primes’, Integers 14 (2014), Article no. A61, 18 pages.Google Scholar
Ramaré, O. and Saouter, Y., ‘Short effective intervals containing primes’, J. Number Theory 98(1) (2003), 1033.10.1016/S0022-314X(02)00029-XCrossRefGoogle Scholar
Selberg, A., ‘On the normal density of primes in small intervals, and the difference between consecutive primes’, Arch. Math. Naturvid. 47(6) (1943), 87105.Google Scholar