Dirichlet's theorem on primes in arithmetic progressions: Difference between revisions

Latest revision as of 00:45, 3 July 2012

Let $a,D$ be relatively prime natural numbers. Then, there exist infinitely many primes $p$ such that:

$p\equiv a{\pmod {D}}$ .

For fixed $a,D$ , the primes that are congruent to $a$ modulo $D$ are termed Dirichlet primes.

Heath-Brown's conjecture on the first Dirichlet prime: A conjecture, saying that the first Dirichlet prime in a given congruence class modulo $D$ is $O(D(\log D)^{2})$ .
Chowla's conjecture on the first Dirichlet prime: A conjecture, saying that the first Dirichlet prime in a given congruence class modulo $D$ is $O(D^{1+\epsilon })$ .
Chowla's corollary to generalized Riemannn hypothesis: Proved conditional to the generalized Riemann hypothesis, saying that the first Dirichlet prime in a given congruence class modulo $D$ is $O(D^{2+\epsilon })$ .
Linnik's theorem: An unconditional theorem, saying that there exists $L>0$ such that the first Dirichlet prime in a given congruence class modulo $D$ is $O(D^{L})$ . Heath-Brown showed that we can take $L=5.5$ .

Green-Tao theorem: This states that for any $k$ , there exists a prime arithmetic progression of length $k$ : an arithmetic progression of length $k$ , all of whose members are primes.

Bunyakovsky conjecture is a conjecture for polynomials of degree two or more whose analogue for linear polynomials would be Dirichlet's theorem.

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 * [[Chebotarev density theorem]]
-===Easy case===
+===Easy cases===
 * [[There are infinitely many primes that are one modulo any modulus]]
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 * [[Green-Tao theorem]]: This states that for any <math>k</math>, there exists a [[prime arithmetic progression]] of length <math>k</math>: an arithmetic progression of length <math>k</math>, all of whose members are primes.
+===Conjectures that generalize to higher degree polynomials===
+* [[Bunyakovsky conjecture]] is a conjecture for polynomials of degree two or more whose analogue for linear polynomials would be Dirichlet's theorem.