Proof of Bertrand's postulate explained

In mathematics, Bertrand's postulate (now a theorem) states that, for each

n\ge2

, there is a prime

such that

n<p<2n

. First conjectured in 1845 by Joseph Bertrand,^[1] it was first proven by Chebyshev, and a shorter but also advanced proof was given by Ramanujan.

(n,2n)

in order to be large enough. This is achieved through analysis of their factorizations.

The main steps of the proof are as follows. First, one shows that the contribution of every prime power factor

p^r

in the prime decomposition of the central binomial coefficient

style\binom{2n}{n}=(2n)!/(n!)²

is at most

; then, one shows that every prime larger than

\sqrt{2n}

appears at most once.

The next step is to prove that

\tbinom{2n}{n}

has no prime factors in the interval

(\tfrac{2n}{3},n)

. As a consequence of these bounds, the contribution to the size of

\tbinom{2n}{n}

coming from the prime factors that are at most

grows asymptotically as

\thetaⁿ

for some

\theta<4

. Since the asymptotic growth of the central binomial coefficient is at least

4^n/2n

, the conclusion is that, by contradiction and for large enough

, the binomial coefficient must have another prime factor, which can only lie between

and

The argument given is valid for all

n\ge427

. The remaining values of

are by direct inspection, which completes the proof.

Lemmas in the proof

The proof uses the following four lemmas to establish facts about the primes present in the central binomial coefficients.

Lemma 1

n>0

, we have

	4ⁿ
	2n

\le\binom{2n}{n}.

Proof: Applying the binomial theorem,

4ⁿ=(1+1)²ⁿ=

	2n
\sum
	k=0

	2n-1
\binom{2n}{k}=2+\sum
	k=1

\binom{2n}{k}\le2n\binom{2n}{n},

since

\tbinom{2n}{n}

is the largest term in the sum in the right-hand side, and the sum has

terms (including the initial

outside the summation).

Lemma 2

For a fixed prime

, define

R=R(n,p)

to be the p-adic order of

\tbinom{2n}{n}

, that is, the largest natural number

such that

p^r

divides

\tbinom{2n}{n}

For any prime

p^R\le2n

Proof: The exponent of

is given by Legendre's formula

	infty
\sum
	j=1

\left\lfloor

	n
	p^j

\right\rfloor,

	infty
R=\sum
	j=1

\left\lfloor

	2n
	p^j

\right\rfloor-

	infty
2\sum
	j=1

\left\lfloor

	n
	p^j

	infty
\right\rfloor=\sum
	j=1

\left(\left\lfloor

	2n
	p^j

\right\rfloor-2\left\lfloor

	n
	p^j

\right\rfloor\right)

But each term of the last summation must be either zero (if

n/p^j\bmod1<1/2

) or one (if

n/p^j\bmod1\ge1/2

), and all terms with

j>log_p(2n)

are zero. Therefore,

R\lelog_p(2n),

and

p^R\le

	log_p(2n)
p

=2n.

Lemma 3

is an odd prime and

	2n
	3

<p\leqn

, then

R(n,p)=0.

Proof: There are exactly two factors of

in the numerator of the expression

\tbinom{2n}{n}=(2n)!/(n!)²

, coming from the two terms

and

(2n)!

, and also two factors of

in the denominator from one copy of the term

in each of the two factors of

. These factors all cancel, leaving no factors of

\tbinom{2n}{n}

. (The bound on

in the preconditions of the lemma ensures that

is too large to be a term of the numerator, and the assumption that

is odd is needed to ensure that

contributes only one factor of

to the numerator.)

Lemma 4

An upper bound is supplied for the primorial function,

n\#=\prod_p\lenp,

where the product is taken over all prime numbers

less than or equal to

For all

n\ge1

n\#<4ⁿ

Proof: We use complete induction.

For

n=1,2

we have

1\#=1<4

and

2\#=2<4²⁼¹⁶

Let us assume that the inequality holds for all

1\len\le2k-1

. Since

n=2k>2

is composite, we have

(2k)\#=(2k-1)\#<4^2k-1<4^2k.

Now let us assume that the inequality holds for all

1\len\le2k

. Since

\binom{2k+1}{k}=	(2k+1)!
	k!(k+1)!

is an integer and all the primes

k+2\lep\le2k+1

appear only in the numerator, we have

	(2k+1)\#	\le\binom{2k+1}{k}=
	(k+1)\#

12\left[\binom{2k+1}{k}+\binom{2k+1}{k+1}\right]<	12(1+1)
	^2k+1

^k.

Therefore,

(2k+1)\#=(k+1)\# ⋅	(2k+1)\#
	(k+1)\#

\le4^k+1\binom{2k+1}{k}<4^k+1 ⋅ 4^k=4^2k+1.

Proof of Bertrand's Postulate

Assume that there is a counterexample: an integer n ≥ 2 such that there is no prime p with n < p < 2n.

If 2 ≤ n < 427, then p can be chosen from among the prime numbers 3, 5, 7, 13, 23, 43, 83, 163, 317, 631 (each being the largest prime less than twice its predecessor) such that n < p < 2n. Therefore, n ≥ 427.

There are no prime factors p of

style\binom{2n}{n}

such that:

2n < p, because every factor must divide (2n)!;
p = 2n, because 2n is not prime;
n < p < 2n, because we assumed there is no such prime number;
2n&hairsp;/&hairsp;3 < p ≤ n: by Lemma 3.

Therefore, every prime factor p satisfies p ≤ 2n&hairsp;/&hairsp;3.

When

p>\sqrt{2n},

the number

style{2n\choosen}

has at most one factor of p. By Lemma 2, for any prime p we have p^R(p,n) ≤ 2n, and

\pi(x)\lex-1

since 1 is neither prime nor composite. Then, starting with Lemma 1 and decomposing the side into its prime factorization, and finally using Lemma 4, these bounds give:

	4ⁿ
	2n

\le\binom{2n}{n}=\left(\prod_p\le\sqrt{2n

}p^\right)\!\!\left(\prod_\!\!\!\!\!\!\!p^\right)<\left(\,\prod_\!\!2n\right)\!\!\left(\prod_\!\!p\right)\le(2n)^4^.Therefore

4^n/3\le(2n)^\sqrt{2n}

, which simplifies to

2^{\sqrt{2n}\le(2n)}^3.

Taking logarithms yields

\sqrt{2n}\le3log_2(2n).

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=426

and it does not for

n=427

, we obtain

n<427.

But these cases have already been settled, and we conclude that no counterexample to the postulate is possible.

Addendum to proof

It is possible to reduce the bound to

n=50

For

n\ge17,

we get

\pi(n)<	n
	2

-1

, so we can say that the product

p^R

is at most

(2n)^0.5\sqrt{2n-1}

, which gives

\begin{align}&	4ⁿ
	2n

\le\binom{2n}{n}\le(2n)^0.5\sqrt{2n-1}4^2n/3\\&4^\sqrt{2n

}\le(2n)^3\\&2\sqrt\le3\log_2(2n)\end

which is true for

n=49

and false for

n=50

External links

Chebyshev's Theorem and Bertrand's Postulate (Leo Goldmakher): https://web.williams.edu/Mathematics/lg5/Chebyshev.pdf
Proof of Bertrand's Postulate (UW Math Circle): https://sites.math.washington.edu/~mathcircle/circle/2013-14/advanced/mc-13a-w10.pdf
Proof in the Mizar system: http://mizar.org/version/current/html/nat_4.html#T56

Proof of Bertrand's postulate explained

Lemmas in the proof

Lemma 1

Lemma 2

Lemma 3

Lemma 4

Proof of Bertrand's Postulate

Addendum to proof

External links

Notes and References