analytic number theory In mathematics, analytic number theory is a branch of number theory that uses methods from mathematical analysis to solve problems about the integers. It is often said to have begun with Peter Gustav Lejeune Dirichlet's 1837 introduction of Dir ...

, Mertens' theorems are three 1874 results related to the density of

prime number A prime number (or a prime) is a natural number greater than 1 that is not a Product (mathematics), product of two smaller natural numbers. A natural number greater than 1 that is not prime is called a composite number. For example, 5 is prime ...

s proved by

Franz Mertens Franz Mertens (20 March 1840 – 5 March 1927) (also known as Franciszek Mertens) was a German-Polish mathematician. He was born in Schroda in the Grand Duchy of Posen, Kingdom of Prussia (now Środa Wielkopolska, Poland) and died in Vienna, Au ...

.F. Mertens. J. reine angew. Math. 78 (1874), 46–6
Ein Beitrag zur analytischen Zahlentheorie
/ref> In the following, let

p\le n

mean all primes not exceeding ''n''.

First theorem

Mertens' first theorem is that :

\sum_ \frac - \log n

does not exceed 2 in absolute value for any

n\ge 2

. ()

Second theorem

Mertens' second theorem is :

\lim_\left(\sum_\frac1p -\log\log n-M\right) =0,

where ''M'' is the Meissel–Mertens constant (). More precisely, Mertens proves that the expression under the limit does not in absolute value exceed :

\frac 4 +\frac 2

for any

n\ge 2

Proof

The main step in the proof of Mertens' second theorem is :

O(n)+n\log n=\log n! =\sum_ \lfloor n/p^k\rfloor\log p =
\sum_ \left(\frac+O(1)\right)\log p= n \sum_\frac\ + O(n)

where the last equality needs

\sum_\log p =O(n)

which follows from

\sum_\log p\le \log=O(n)

. Thus, we have proved that :

\sum_\frac=\log n+O(1)

. Since the sum over prime powers with

k \ge 2

converges, this implies :

\sum_\frac=\log n+O(1)

. A partial summation yields :

\sum_ \frac1 = \log\log n+M+O(1/\log n)

Changes in sign

In a paper on the growth rate of the sum-of-divisors function published in 1983, Guy Robin proved that in Mertens' 2nd theorem the difference :

\sum_\frac1p -\log\log n-M

changes sign infinitely often, and that in Mertens' 3rd theorem the difference :

\log n\prod_\left(1-\frac1p\right)-e^

changes sign infinitely often. Robin's results are analogous to Littlewood's famous theorem that the difference π(''x'') − li(''x'') changes sign infinitely often. No analog of the Skewes number (an upper bound on the first

natural number In mathematics, the natural numbers are the numbers 0, 1, 2, 3, and so on, possibly excluding 0. Some start counting with 0, defining the natural numbers as the non-negative integers , while others start with 1, defining them as the positive in ...

''x'' for which π(''x'') > li(''x'')) is known in the case of Mertens' 2nd and 3rd theorems.

Relation to the prime number theorem

Regarding this asymptotic formula Mertens refers in his paper to "two curious formula of Legendre", the first one being Mertens' second theorem's prototype (and the second one being Mertens' third theorem's prototype: see the very first lines of the paper). He recalls that it is contained in Legendre's third edition of his "Théorie des nombres" (1830; it is in fact already mentioned in the second edition, 1808), and also that a more elaborate version was proved by

Chebyshev Pafnuty Lvovich Chebyshev ( rus, Пафну́тий Льво́вич Чебышёв, p=pɐfˈnutʲɪj ˈlʲvovʲɪtɕ tɕɪbɨˈʂof) ( – ) was a list of Russian mathematicians, Russian mathematician and considered to be the founding father o ...

in 1851. Note that, already in 1737,

Euler Leonhard Euler ( ; ; ; 15 April 170718 September 1783) was a Swiss polymath who was active as a mathematician, physicist, astronomer, logician, geographer, and engineer. He founded the studies of graph theory and topology and made influential ...

knew the asymptotic behaviour of this sum. Mertens diplomatically describes his proof as more precise and rigorous. In reality none of the previous proofs are acceptable by modern standards: Euler's computations involve the infinity (and the hyperbolic

logarithm In mathematics, the logarithm of a number is the exponent by which another fixed value, the base, must be raised to produce that number. For example, the logarithm of to base is , because is to the rd power: . More generally, if , the ...

of infinity, and the logarithm of the logarithm of infinity!); Legendre's argument is

heuristic A heuristic or heuristic technique (''problem solving'', '' mental shortcut'', ''rule of thumb'') is any approach to problem solving that employs a pragmatic method that is not fully optimized, perfected, or rationalized, but is nevertheless ...

; and Chebyshev's proof, although perfectly sound, makes use of the Legendre-Gauss conjecture, which was not proved until 1896 and became better known as the

prime number theorem In mathematics, the prime number theorem (PNT) describes the asymptotic analysis, asymptotic distribution of the prime numbers among the positive integers. It formalizes the intuitive idea that primes become less common as they become larger by p ...

. Mertens' proof does not appeal to any unproved hypothesis (in 1874), and only to elementary

real analysis In mathematics, the branch of real analysis studies the behavior of real numbers, sequences and series of real numbers, and real functions. Some particular properties of real-valued sequences and functions that real analysis studies include co ...

. It comes 22 years before the first proof of the prime number theorem which, by contrast, relies on a careful analysis of the behavior of the

Riemann zeta function The Riemann zeta function or Euler–Riemann zeta function, denoted by the Greek letter (zeta), is a mathematical function of a complex variable defined as \zeta(s) = \sum_^\infty \frac = \frac + \frac + \frac + \cdots for and its analytic c ...

as a function of a complex variable. Mertens' proof is in that respect remarkable. Indeed, with modern notation it yields :

\sum_\frac1p=\log\log x+M+O(1/\log x)

whereas the prime number theorem (in its simplest form, without error estimate), can be shown to imply :

\sum_\frac1p=\log\log x+M+o(1/\log x).

In 1909

Edmund Landau Edmund Georg Hermann Landau (14 February 1877 – 19 February 1938) was a German mathematician who worked in the fields of number theory and complex analysis. Biography Edmund Landau was born to a Jewish family in Berlin. His father was Leopo ...

, by using the best version of the prime number theorem then at his disposition, provedEdmund Landau. Handbuch der Lehre von der Verteilung der Primzahlen, Teubner, Leipzig 1909, Repr. Chelsea New York 1953, § 55, p. 197-203. that :

\sum_\frac1p=\log\log x+M+O(e^)

holds; in particular the error term is smaller than

1/(\log x)^k

for any fixed integer ''k''. A simple

summation by parts In mathematics, summation by parts transforms the summation of products of sequences into other summations, often simplifying the computation or (especially) estimation of certain types of sums. It is also called Abel's lemma or Abel transformati ...

exploiting the strongest form known of the prime number theorem improves this to :

\sum_\frac1p=\log\log x+M+O(e^)

for some

c > 0

. Similarly a partial summation shows that

\sum_ \frac = \log x+ C+o(1)

is implied by the PNT.

Third theorem

Mertens' third theorem is :

\lim_\log n\prod_\left(1-\frac1p\right)=e^ \approx 0.561459483566885,

where γ is the

Euler–Mascheroni constant Euler's constant (sometimes called the Euler–Mascheroni constant) is a mathematical constant, usually denoted by the lowercase Greek letter gamma (), defined as the limiting difference between the harmonic series and the natural logarith ...

().

Relation to sieve theory

An estimate of the probability of

X

(

X \gg n

) having no factor

\le n

is given by :

\prod_\left(1-\frac1p\right)

This is closely related to Mertens' third theorem which gives an asymptotic approximation of :

P(p \nmid X\ \forall p \le n) = \frac

References

External links

*{{MathWorld, urlname=MertensConstant, title=Mertens Constant Series (mathematics) Summability theory Theorems about prime numbers