Chowla's conjecture on the first Dirichlet prime: Difference between revisions

Latest revision as of 03:35, 9 February 2010

Template:Primes in arithmetic progressions conjecture

Statement

Quick statement

The first Dirichlet prime in any relatively prime congruence class modulo $D$ is $O (D^{1 + ϵ})$ .

In terms of the first Dirichlet prime

For any $ϵ > 0$ , there exists a constant $C$ such that the following holds:

Suppose $a$ and $D$ are relatively prime natural numbers. Then, there exists a prime $p \equiv a (\mod D)$ such that $p < C D^{1 + ϵ}$ .

In terms of the first few Dirichlet primes

For any $ϵ > 0$ and any natural number $k$ , there exists a constant $C$ such that the following holds:

Suppose $a$ and $D$ are relatively prime natural numbers. Then, there exist at least $k$ distinct primes $p \equiv a (\mod D)$ such that $p < C D^{1 + ϵ}$ .

This follows from the version involving the first Dirichlet prime.

Relation with other facts

Stronger conjectures

Heath-Brown's conjecture on the first Dirichlet prime

Weaker facts and conjectures

Chowla's corollary to generalized Riemann hypothesis: Under the generalized Riemann hypothesis, we have the analogous result for $2 + ϵ$ instead of $1 + ϵ$ .
Linnik's theorem: This is an unconditional version where $1 + ϵ$ is replaced by some large constant $L$ . Heath-Brown has shown that $L \leq 5.5$ .

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 ===Weaker facts and conjectures===
-* [[Stronger than::Chowla's corollary to generalized Riemann hypothesis]]: Under the [generalized Riemann hypothesis]], we have the analogous result for <math>2 + \epsilon</math> instead of <math>1 + \epsilon</math>.
+* [[Stronger than::Chowla's corollary to generalized Riemann hypothesis]]: Under the [[generalized Riemann hypothesis]], we have the analogous result for <math>2 + \epsilon</math> instead of <math>1 + \epsilon</math>.
-* [[Stronger than::Linnick's theorem]]: This is an unconditional version where <math>1 + \epsilon</math> is replaced by some large constant <math>L</math>. Heath-Brown have shown that <math>L \le 5.5</math>.
+* [[Stronger than::Linnik's theorem]]: This is an unconditional version where <math>1 + \epsilon</math> is replaced by some large constant <math>L</math>. Heath-Brown has shown that <math>L \le 5.5</math>.