Proof of Bertrand's postulate


In mathematics, Bertrand's postulate states that for each there is a prime such that. It was first proven by Pafnuty Chebyshev, and a short but advanced proof was given by Srinivasa Ramanujan. The gist of the following elementary proof is due to Paul Erdős. The basic idea of the proof is to show that a certain central binomial coefficient needs to have a prime factor within the desired interval in order to be large enough. This is made possible by a careful analysis of the prime factorization of central binomial coefficients.
The main steps of the proof are as follows. First, one shows that every prime power factor that enters into the prime decomposition of
the central binomial coefficient is at most. In particular, every prime larger than can enter at most once into this decomposition; that is, its exponent is at most one. The next step is to prove that has no prime factors at all in the gap interval. As a consequence of these two bounds, the contribution to the size of coming from all the prime factors that are at most grows asymptotically as for some. Since the
asymptotic growth of the central binomial coefficient is at least, one concludes that for large enough the binomial coefficient must have another prime factor, which can only lie between and.
Indeed, making these estimates quantitative, one obtains that this argument is valid for all. The remaining smaller values of are easily settled by direct inspection, completing the proof of Bertrand's postulate. This proof is so short and elegant that it is considered to be one of the Proofs from THE BOOK.

Lemmas and computation

Lemma 1: A lower bound on the central binomial coefficients

Lemma: For any integer, we have
Proof: Applying the binomial theorem,
since is the largest term in the sum in the right-hand side, and the sum has terms.

Lemma 2: An upper bound on prime powers dividing central binomial coefficients

For a fixed prime, define to be the largest natural number such that divides.
Lemma: For any prime,.
Proof: The exponent of in is :
so
But each term of the last summation can either be zero or 1 and all terms with are zero. Therefore,
and
This completes the proof of the lemma.

Lemma 3: Central binomial coefficients have no prime factor in a large interval

Claim: If is odd and, then
Proof: There are exactly two factors of in the numerator of the expression, coming from the two terms and in, and also two factors of in the denominator from two copies of the term in. These factors all cancel, leaving no factors of in..

Lemma 4: An upper bound on the primorial

We estimate the primorial function,
where the product is taken over all prime numbers less than or equal to the real number
Lemma: For all real numbers,
Proof:
Since and, it suffices to prove the result under the assumption that is an integer, Since is an integer and all the primes appear in its numerator but not in its denominator, we have
The proof proceeds by complete induction on
Thus the lemma is proven.

Proof of Bertrand's Postulate

Assume there is a counterexample: an integer n ≥ 2 such that there is no prime p with n < p < 2n.
If 2 ≤ n < 468, then p can be chosen from among the prime numbers 3, 5, 7, 13, 23, 43, 83, 163, 317, 631 such that n < p < 2n. Therefore, n ≥ 468.
There are no prime factors p of such that:
Therefore, every prime factor p satisfies p ≤ 2n/3.
When the number has at most one factor of p. By [|Lemma 2], for any prime p we have pR ≤ 2n, so the product of the pR over the primes less than or equal to is at most. Then, starting with [|Lemma 1] and decomposing the right-hand side into its prime factorization, and finally using [|Lemma 4], these bounds give:
Taking logarithms yields to
By concavity of the right-hand side as a function of n, the last inequality is necessarily verified on an interval. Since it holds true for n=467 and it does not for n=468, we obtain
But these cases have already been settled, and we conclude that no counterexample to the postulate is possible.