Second Hardy–Littlewood conjecture

Second Hardy–Littlewood conjecture
Plot of $\pi (x)+\pi (y)-\pi (x+y)$ for $x,y\leq 200$
Field	Number theory
Conjectured by	G. H. Hardy John Edensor Littlewood
Conjectured in	1923
Open problem	yes

In number theory, the second Hardy–Littlewood conjecture concerns the number of primes in intervals. Along with the first Hardy–Littlewood conjecture, the second Hardy–Littlewood conjecture was proposed by G. H. Hardy and John Edensor Littlewood in 1923.^[1]

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Statement

The conjecture states that

$\pi (x+y)\leq \pi (x)+\pi (y)$

for integers $x, y \geq 2$ , where $π (z)$ denotes the prime-counting function, giving the number of prime numbers up to and including $z$ .

Connection to the first Hardy–Littlewood conjecture

The statement of the second Hardy–Littlewood conjecture is equivalent to the statement that the number of primes from $x + 1$ to $x + y$ is always less than or equal to the number of primes from 1 to $y$ . This was proved to be inconsistent with the first Hardy–Littlewood conjecture on prime $k$ -tuples, and the first violation is expected to likely occur for very large values of $x$ .^[2]^[3] For example, an admissible k-tuple (or prime constellation) of 447 primes can be found in an interval of $y = 3159$ integers, while $π (3159) = 446$ . If the first Hardy–Littlewood conjecture holds, then the first such $k$ -tuple is expected for $x$ greater than $1.5 \times 10 174$ but less than $2.2 \times 10 1198$ .^[4]

References

^ Hardy, G. H.; Littlewood, J. E. (1923). "Some Problems of 'Partitio Numerorum.' III. On the Expression of a Number as a Sum of Primes". Acta Math. 44 (44): 1–70. doi:10.1007/BF02403921..
^ Hensley, Douglas; Richards, Ian. "Primes in intervals". Acta Arith. 25 (1973/74): 375–391. doi:10.4064/aa-25-4-375-391. MR 0396440.
^ Richards, Ian (1974). "On the Incompatibility of Two Conjectures Concerning Primes". Bull. Amer. Math. Soc. 80: 419–438. doi:10.1090/S0002-9904-1974-13434-8.
^ "447-tuple calculations". Retrieved 2008-08-12.

External links

Engelsma, Thomas J. "k-tuple Permissible Patterns". Retrieved 2008-08-12.
Oliveira e Silva, Tomás. "Admissible prime constellations". Retrieved 2023-09-28.

v t e Prime number conjectures
Hardy–Littlewood 1st 2nd Agoh–Giuga Andrica's Artin's Bateman–Horn Brocard's Bunyakovsky Chinese hypothesis Cramér's Dickson's Elliott–Halberstam Firoozbakht's Gilbreath's Grimm's Landau's problems Goldbach's weak Legendre's Twin prime Legendre's constant Lemoine's Mersenne Oppermann's Polignac's Pólya Schinzel's hypothesis H Waring's prime number

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