In number theory, Selberg's identity is an approximate identity involving logarithms of primes named after Atle Selberg. The identity, discovered jointly by Selberg and Paul Erdős, was used in the first elementary proof for the prime number theorem.
Statement
editThere are several different but equivalent forms of Selberg's identity. One form is
where the sums are over primes p and q.
Explanation
editThe strange-looking expression on the left side of Selberg's identity is (up to smaller terms) the sum
where the numbers
are the coefficients of the Dirichlet series
This function has a pole of order 2 at s = 1 with coefficient 2, which gives the dominant term 2x log(x) in the asymptotic expansion of
Another variation of the identity
editSelberg's identity sometimes also refers to the following divisor sum identity involving the von Mangoldt function and the Möbius function when :[1]
This variant of Selberg's identity is proved using the concept of taking derivatives of arithmetic functions defined by in Section 2.18 of Apostol's book (see also this link).
References
edit- ^ Apostol, T. (1976). Introduction to Analytic Number Theory. New York: Springer. p. 46 (Section 2.19). ISBN 0-387-90163-9.
- Pisot, Charles (1949), Démonstration élémentaire du théorème des nombres premiers, Séminaire Bourbaki, vol. 1, MR 1605145
- Selberg, Atle (1949), "An elementary proof of the prime-number theorem", Ann. of Math., 2, 50 (2): 305–313, doi:10.2307/1969455, JSTOR 1969455, MR 0029410