In number theory, Maier's theorem is a theorem about the numbers of primes in short intervals for which Cramér's probabilistic model of primes gives a wrong answer.
The theorem states that if π is the prime-counting function and λ is greater than 1 then
| \pi(x+(logx)λ)-\pi(x) | |
| (logx)λ-1 |
does not have a limit as x tends to infinity; more precisely the limit superior is greater than 1, and the limit inferior is less than 1. The Cramér model of primes predicts incorrectly that it has limit 1 when λ≥2 (using the Borel–Cantelli lemma).
Maier proved his theorem using Buchstab's equivalent for the counting function of quasi-primes (set of numbers without prime factors lower to bound
z=x1/u
u
gave another proof, and also showed that most probabilistic models of primes incorrectly predict the mean square error
| Y\left(\sum | |
| \int | |
| 2<p\lex |
logp-\sum2<n\le1\right)2dx
of one version of the prime number theorem.