The hypothesis claims that for every finite collection ${\displaystyle \{f_{1},f_{2},\ldots ,f_{k}\}}$  of nonconstant irreducible polynomials over the integers with positive leading coefficients, one of the following conditions holds:

1. There are infinitely many positive integers ${\displaystyle n}$  such that all of ${\displaystyle f_{1}(n),f_{2}(n),\ldots ,f_{k}(n)}$  are simultaneously prime numbers, or
2. There is an integer ${\displaystyle m>1}$  (called a "fixed divisor"), which depends on the polynomials, which always divides the product ${\displaystyle f_{1}(n)f_{2}(n)\cdots f_{k}(n)}$ . (Or, equivalently: There exists a prime ${\displaystyle p}$  such that for every ${\displaystyle n}$  there is an ${\displaystyle i}$  such that ${\displaystyle p}$  divides ${\displaystyle f_{i}(n)}$ .)

The second condition is satisfied by sets such as ${\displaystyle f_{1}(x)=x+4,f_{2}(x)=x+7}$ , since ${\displaystyle (x+4)(x+7)}$  is always divisible by 2. It is easy to see that this condition prevents the first condition from being true. Schinzel's hypothesis essentially claims that condition 2 is the only way condition 1 can fail to hold.

No effective technique is known for determining whether the first condition holds for a given set of polynomials, but the second one is straightforward to check: Let ${\displaystyle Q(x)=f_{1}(x)f_{2}(x)\cdots f_{k}(x)}$  and compute the greatest common divisor of ${\displaystyle \deg(Q)+1}$  successive values of ${\displaystyle Q(n)}$ . One can see by extrapolating with finite differences that this divisor will also divide all other values of ${\displaystyle Q(n)}$  too.

Schinzel's hypothesis builds on the earlier Bunyakovsky conjecture, for a single polynomial, and on the Hardy–Littlewood conjectures and Dickson's conjecture for multiple linear polynomials. It is in turn extended by the Bateman–Horn conjecture.

Examples edit

As a simple example with ${\displaystyle k=1}$ ,

${\displaystyle x^{2}+1}$ 

has no fixed prime divisor. We therefore expect that there are infinitely many primes

${\displaystyle n^{2}+1}$ 

This has not been proved, though. It was one of Landau's conjectures and goes back to Euler, who observed in a letter to Goldbach in 1752 that ${\displaystyle n^{2}+1}$  is often prime for ${\displaystyle n}$  up to 1500.

As another example, take ${\displaystyle k=2}$  with ${\displaystyle f_{1}(x)=x}$  and ${\displaystyle f_{2}(x)=x+2}$ . The hypothesis then implies the existence of infinitely many twin primes, a basic and notorious open problem.

Variants edit

As proved by Schinzel and Sierpiński^[1] it is equivalent to the following: if condition 2 does not hold, then there exists at least one positive integer ${\displaystyle n}$  such that all ${\displaystyle f_{i}(n)}$  will be simultaneously prime, for any choice of irreducible integral polynomials ${\displaystyle f_{i}(x)}$  with positive leading coefficients.

If the leading coefficients were negative, we could expect negative prime values; this is a harmless restriction.

There is probably no real reason to restrict polynomials with integer coefficients, rather than integer-valued polynomials (such as ${\displaystyle {\tfrac {1}{2}}x^{2}+{\tfrac {1}{2}}x+1}$ , which takes integer values for all integers ${\displaystyle x}$  even though the coefficients are not integers).

The special case of a single linear polynomial is Dirichlet's theorem on arithmetic progressions, one of the most important results of number theory. In fact, this special case is the only known instance of Schinzel's Hypothesis H. We do not know the hypothesis to hold for any given polynomial of degree greater than ${\displaystyle 1}$ , nor for any system of more than one polynomial.

Almost prime approximations to Schinzel's Hypothesis have been attempted by many mathematicians; among them, most notably, Chen's theorem states that there exist infinitely many prime numbers ${\displaystyle n}$  such that ${\displaystyle n+2}$  is either a prime or a semiprime ^[2] and Iwaniec proved that there exist infinitely many integers ${\displaystyle n}$  for which ${\displaystyle n^{2}+1}$  is either a prime or a semiprime.^[3] Skorobogatov and Sofos have proved that almost all polynomials of any fixed degree satisfy Schinzel's hypothesis H.^[4]

Let ${\displaystyle P(x)}$  be an integer-valued polynomial with common factor ${\displaystyle d}$ , and let ${\displaystyle Q(x)={\frac {P(x)}{d}}}$ . Then ${\displaystyle Q(x)}$  is an primitive integer-valued polynomial. Ronald Joseph Miech proved using Brun sieve that ${\displaystyle \Omega (Q(n))\leq k}$  infinitely often and therefore ${\displaystyle \Omega (P(n))\leq m}$  infinitely often, where ${\displaystyle n}$  runs over positive integers. The numbers ${\displaystyle k}$  and ${\displaystyle m=k+\Omega (d)}$  don't depend on ${\displaystyle n}$ , and ${\displaystyle k\leq n\cdot (\ln(n)+2.8)}$ . This theorem is also known as Miech's theorem.

If there is a hypothetical probabilistic density sieve, using the Miech's theorem can prove the Schinzel's hypothesis H in all cases by mathematical induction.

The hypothesis is probably not accessible with current methods in analytic number theory, but is now quite often used to prove conditional results, for example in Diophantine geometry. This connection is due to Jean-Louis Colliot-Thélène and Jean-Jacques Sansuc.^[5] For further explanations and references on this connection see the notes of Swinnerton-Dyer.^[6] The conjectural result being so strong in nature, it is possible that it could be shown to be too much to expect.

The hypothesis does not cover Goldbach's conjecture, but a closely related version (hypothesis H_N) does. That requires an extra polynomial ${\displaystyle F(x)}$ , which in the Goldbach problem would just be ${\displaystyle x}$ , for which

N − F(n)

is required to be a prime number, also. This is cited in Halberstam and Richert, Sieve Methods. The conjecture here takes the form of a statement when N is sufficiently large, and subject to the condition that

${\displaystyle f_{1}(n)f_{2}(n)\cdots f_{k}(n)(N-F(n))}$ 

has no fixed divisor > 1. Then we should be able to require the existence of n such that N − F(n) is both positive and a prime number; and with all the f_i(n) prime numbers.

Not many cases of these conjectures are known; but there is a detailed quantitative theory (see Bateman–Horn conjecture).

The condition of having no fixed prime divisor is purely local (depending just on primes, that is). In other words, a finite set of irreducible integer-valued polynomials with no local obstruction to taking infinitely many prime values is conjectured to take infinitely many prime values.

The analogous conjecture with the integers replaced by the one-variable polynomial ring over a finite field is false. For example, Swan noted in 1962 (for reasons unrelated to Hypothesis H) that the polynomial

${\displaystyle x^{8}+u^{3}\,}$ 

over the ring F₂[u] is irreducible and has no fixed prime polynomial divisor (after all, its values at x = 0 and x = 1 are relatively prime polynomials) but all of its values as x runs over F₂[u] are composite. Similar examples can be found with F₂ replaced by any finite field; the obstructions in a proper formulation of Hypothesis H over F[u], where F is a finite field, are no longer just local but a new global obstruction occurs with no classical parallel, assuming hypothesis H is in fact correct.

• Crandall, Richard; Pomerance, Carl B. (2005). Prime Numbers: A Computational Perspective (Second ed.). New York: Springer-Verlag. doi:10.1007/0-387-28979-8. ISBN 0-387-25282-7. MR 2156291. Zbl 1088.11001.
• Guy, Richard K. (2004). Unsolved problems in number theory (Third ed.). Springer-Verlag. ISBN 978-0-387-20860-2. Zbl 1058.11001.
• Pollack, Paul (2008). "An explicit approach to hypothesis H for polynomials over a finite field". In De Koninck, Jean-Marie; Granville, Andrew; Luca, Florian (eds.). Anatomy of integers. Based on the CRM workshop, Montreal, Canada, March 13–17, 2006. CRM Proceedings and Lecture Notes. Vol. 46. Providence, RI: American Mathematical Society. pp. 259–273. ISBN 978-0-8218-4406-9. Zbl 1187.11046.
• Swan, R. G. (1962). "Factorization of Polynomials over Finite Fields". Pacific Journal of Mathematics. 12 (3): 1099–1106. doi:10.2140/pjm.1962.12.1099.