Brun sieve

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In the field of number theory, the Brun sieve (also called Brun's pure sieve) is a technique for estimating the size of "sifted sets" of positive integers which satisfy a set of conditions which are expressed by congruences. It was developed by Viggo Brun in 1915.

Description

In terms of sieve theory the Brun sieve is of combinatorial type: that is, derives from a careful use of the inclusion-exclusion principle.

Let A be a set of positive integers ≤ x and let P be a set of primes. For each p in P, let A_p denote the set of elements of A divisible by p and extend this to let A_d the intersection of the A_p for p dividing d, when d is a product of distinct primes from P. Further let A₁ denote A itself. Let z be a positive real number and P(z) denote the primes in P ≤ z. The object of the sieve is to estimate

$S(A,P,z)=\left\vert A\setminus \bigcup _{{p\in P(z)}}A_{p}\right\vert .$

We assume that |A_d| may be estimated by

$\left\vert A_{d}\right\vert ={\frac {w(d)}{d}}X+R_{d}$

where w is a multiplicative function and X = |A|. Let

$W(z)=\prod _{{p\in P(z)}}\left(1-{\frac {w(p)}{p}}\right).$

Brun's pure sieve

This formulation is from Cojocaru & Murty, Theorem 6.1.2. With the notation as above, assume that

|R_d| ≤ w(d) for any squarefree d composed of primes in P ;
w(p) < C for all p in P ;
$\sum _{{p\in P_{z}}}{\frac {w(p)}{p}}<D\log \log z+E;$

where C, D, E are constants.

Then

$S(A,P,z)=X\cdot W(z)\cdot \left({1+O\left((\log z)^{{-b\log b}}\right)}\right)+O\left(z^{{b\log \log z}}\right).$

In particular, if log z < c log x / log log x for a suitably small c, then

$S(A,P,z)=X\cdot W(z)(1+o(1)).\,$

Applications

Brun's theorem: the sum of the reciprocals of the twin primes converges;
Schnirelmann's theorem: every even number is a sum of at most C primes (where C can be taken to be 6);
There are infinitely many pairs of integers differing by 2, where each of the member of the pair is the product of at most 9 primes;
Every even number is the sum of two numbers each of which is the product of at most 9 primes.

The last two results were superseded by Chen's theorem.

References

Viggo Brun (1915). "Über das Goldbachsche Gesetz und die Anzahl der Primzahlpaare". Archiv for Mathematik og Naturvidenskab B34 (8).
Viggo Brun (1919). "La série 1/5+1/7+1/11+1/13+1/17+1/19+1/29+1/31+1/41+1/43+1/59+1/61+..., où les dénominateurs sont nombres premiers jumeaux est convergente ou finie". Bulletin des Sciences Mathématiques 43: 100–104,124–128.
Alina Carmen Cojocaru; M. Ram Murty (2005). An introduction to sieve methods and their applications. London Mathematical Society Student Texts 66. Cambridge University Press. pp. 80–112. ISBN 0-521-61275-6. Cite uses deprecated parameters (help)
George Greaves (2001). Sieves in number theory. Ergebnisse der Mathematik und ihrer Grenzgebiete (3. Folge) 43. Springer-Verlag. pp. 71–101. ISBN 3-540-41647-1.
Heini Halberstam; H.E. Richert (1974). Sieve Methods. Academic Press. ISBN 0-12-318250-6. Cite uses deprecated parameters (help)
Christopher Hooley (1976). Applications of sieve methods to the theory of numbers. Cambridge University Press. ISBN 0-521-20915-3. .

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