explicit formulae for L-functions

In his 1859 paper "On the Number of Primes Less Than a Given Magnitude" Riemann sketched an explicit formula (it was not fully proven until 1895 by von Mangoldt, see below) for the normalized prime-counting function {{math|π₀(x)}} which is related to the prime-counting function {{math|π(x)}} by{{cn|date=February 2024}}

:$\backslash pi\_0(x)\; =\; \backslash frac\{1\}\{2\}\; \backslash lim\_\{h\backslash to\; 0\}\; \backslash left[\backslash ,\backslash pi(x+h)\; +\; \backslash pi(x-h)\backslash ,\backslash right]\backslash ,,$

which takes the arithmetic mean of the limit from the left and the limit from the right at discontinuities.{{efn|The original prime counting function can easily be recovered via $~\backslash pi(x)\; =\; \backslash pi\_0(x+1)~$ for all $~x\; \backslash ge\; 3~.$}} His formula was given in terms of the related function

:$f(x)\; =\; \backslash pi\_0(x)\; +\; \backslash frac\{1\}\{2\}\backslash ,\backslash pi\_0(x^\{1/2\})\; +\; \backslash frac\{1\}\{3\}\backslash ,\backslash pi\_0(x^\{1/3\})\; +\; \backslash cdots$

in which a prime power {{math|pⁿ}} counts as {{frac|1|{{mvar|n}}}} of a prime. The normalized prime-counting function can be recovered from this function by

:{{Cite journal |last=Li |first=Xian-Jin |date=April 2004 |title=Explicit formulas for Dirichlet and Hecke $L$-functions |journal=Illinois Journal of Mathematics |volume=48 |issue=2 |pages=491–503 |doi=10.1215/ijm/1258138394 |issn=0019-2082|doi-access=free }}$\backslash pi\_0(x)\; =\; \backslash sum\_n\backslash frac\{1\}\{n\}\backslash ,\backslash mu(n)\backslash ,f(x^\{1/n\})\; =\; f(x)\; -\; \backslash frac\{1\}\{2\}\backslash ,f(x^\{1/2\})\; -\; \backslash frac\{1\}\{3\}\backslash ,f(x^\{1/3\})\; -\; \backslash frac\{1\}\{5\}\backslash ,f(x^\{1/5\})\; +\; \backslash frac\{1\}\{6\}\backslash ,f(x^\{1/6\})\; -\; \backslash cdots,$

where {{math|μ(n)}} is the Möbius function. Riemann's formula is then

:$f(x)\; =\; \backslash operatorname\{li\}(x)\; -\; \backslash sum\_\backslash rho\; \backslash operatorname\{li\}(x^\backslash rho)\; -\; \backslash log(2)\; +\; \backslash int\_x^\backslash infty\; \backslash frac\{dt\}\{~t\backslash ,(t^2-1)~\backslash log(t)~\}$

involving a sum over the non-trivial zeros {{mvar|ρ}} of the Riemann zeta function. The sum is not absolutely convergent, but may be evaluated by taking the zeros in order of the absolute value of their imaginary part. The function {{math|li}} occurring in the first term is the (unoffset) logarithmic integral function given by the Cauchy principal value of the divergent integral

:$\backslash operatorname\{li\}(x)\; =\; \backslash int\_0^x\; \backslash frac\{dt\}\{\backslash ,\backslash log(t)\backslash ,\}\backslash ,.$

The terms {{math|li(x^ρ)}} involving the zeros of the zeta function need some care in their definition as {{math|li}} has branch points at 0 and 1, and are defined by analytic continuation in the complex variable {{mvar|ρ}} in the region {{math|x > 1}} and {{math|Re(ρ) > 0}}. The other terms also correspond to zeros: The dominant term {{math|li(x)}} comes from the pole at {{math|s {{=}} 1}}, considered as a zero of multiplicity −1, and the remaining small terms come from the trivial zeros. This formula says that the zeros of the Riemann zeta function control the oscillations of primes around their "expected" positions. (For graphs of the sums of the first few terms of this series see {{harvnb|Zagier|1977}}.)

The first rigorous proof of the aforementioned formula was given by von Mangoldt in 1895: it started with a proof of the following formula for the Chebyshev's function {{mvar|ψ}} Weisstein, Eric W. [http://mathworld.wolfram.com/ExplicitFormula.html Explicit Formula] on MathWorld.

:$\backslash psi\_0(x)\; =\; \backslash dfrac\{1\}\{2\backslash pi\; i\}\; \backslash int\_\{\backslash sigma-i\; \backslash infty\}^\{\backslash sigma+i\; \backslash infty\}\backslash left(-\backslash dfrac\{\backslash zeta\text{'}(s)\}\{\backslash zeta(s)\}\backslash right)\backslash dfrac\{x^s\}\{s\}\backslash ,\; ds\; =\; x\; -\; \backslash sum\_\backslash rho\backslash frac\{~x^\backslash rho\backslash ,\}\{\backslash rho\}\; -\; \backslash log(2\backslash pi)\; -\backslash dfrac\{1\}\{2\}\backslash log(1-x^\{-2\})$

where the LHS is an inverse Mellin transform with

:$\backslash sigma\; >\; 1\backslash ,,\; \backslash quad\; \backslash psi(x)\; =\; \backslash sum\_\{p^k\; \backslash le\; x\}\; \backslash log\; p\backslash ,,$

\quad \text{and} \quad \psi_0(x) = \frac{1}{2} \lim_{h\to 0} (\psi(x+h) + \psi(x-h))

and the RHS is obtained from the residue theorem, and then converting it into the formula that Riemann himself actually sketched.

This series is also conditionally convergent and the sum over zeroes should again be taken in increasing order of imaginary part:Ingham (1990) p.77

:$\backslash sum\_\backslash rho\backslash frac\{x^\backslash rho\}\{\backslash rho\}\; =\; \backslash lim\_\{T\; \backslash to\; \backslash infty\}\; S(x,T)$ {{pad|2em}} where {{pad|2em}} $S(x,T)\; =\; \backslash sum\_\{\backslash rho:\backslash left|\backslash Im\; \backslash rho\backslash right|\; \backslash le\; T\}\; \backslash frac\{x^\backslash rho\}\{\backslash rho\}\backslash ,.$

The error involved in truncating the sum to {{math|S(x,T)}} is always smaller than {{math|ln(x)}} in absolute value, and when divided by the natural logarithm of {{mvar|x}}, has absolute value smaller than {{math|{{frac|x|T}}}} divided by the distance from {{mvar|x}} to the nearest prime power.[https://math.stackexchange.com/q/497949 Confused about the explicit formula for ψ0(x)]

There are several slightly different ways to state the explicit formula.{{Cite web |title=the Riemann-Weil explicit formula |url=https://empslocal.ex.ac.uk/people/staff/mrwatkin/zeta/weilexplicitformula.htm |access-date=2023-06-14 |website=empslocal.ex.ac.uk}} André Weil's form of the explicit formula states

:$$

\begin{align}

& \Phi(1)+\Phi(0)-\sum_\rho\Phi(\rho) \\

& = \sum_{p,m} \frac{\log(p)}{p^{m/2}} \Big ( F(\log(p^m)) + F(-\log(p^m)) \Big ) - \frac{1}{2\pi} \int_{-\infty}^\infty \varphi(t)\Psi(t)\,dt

\end{align}

where

• ρ runs over the non-trivial zeros of the zeta function
• p runs over positive primes
• m runs over positive integers
• F is a smooth function all of whose derivatives are rapidly decreasing
• $\backslash varphi$ is a Fourier transform of F: $$\backslash varphi(t)\; =\; \backslash int\_\{-\backslash infty\}^\backslash infty\; F(x)e^\{itx\}\backslash ,dx$$
• $\backslash Phi(1/2\; +\; it)\; =\; \backslash varphi(t)$
• $\backslash Psi(t)\; =\; -\; \backslash log(\; \backslash pi\; )\; +\; \backslash operatorname\{Re\}(\backslash psi(1/4\; +\; it/2))$, where $\backslash psi$ is the digamma function {{math|Γ′/Γ}}.

Roughly speaking, the explicit formula says the Fourier transform of the zeros of the zeta function is the set of prime powers plus some elementary factors. Once this is said, the formula comes from the fact that the Fourier transform is a unitary operator, so that a scalar product in time domain is equal to the scalar product of the Fourier transforms in the frequency domain.

The terms in the formula arise in the following way.

• The terms on the right hand side come from the logarithmic derivative of $$\backslash zeta^*(s)=\; \backslash Gamma(s/2)\backslash pi^\{-s/2\}\backslash prod\_p\; \backslash frac\{1\}\{1-p^\{-s\}\}$$ with the terms corresponding to the prime p coming from the Euler factor of p, and the term at the end involving Ψ coming from the gamma factor (the Euler factor at infinity).
• The left-hand side is a sum over all zeros of ζ ^* counted with multiplicities, so the poles at 0 and 1 are counted as zeros of order −1.

Weil's explicit formula can be understood like this. The target is to be able to write that:

: $\backslash frac\{d\}\{du\}\; \backslash left[\; \backslash sum\_\{n\; \backslash le\; e^$

where {{math|Λ}} is the von Mangoldt function.

So that the Fourier transform of the non trivial zeros is equal to the primes power symmetrized plus a minor term. Of course, the sum involved are not convergent, but the trick is to use the unitary property of Fourier transform which is that it preserves scalar product:

: $\backslash int\_\{-\backslash infty\}^\backslash infty\; f(u)\; g^*(u)\; \backslash ,\; du\; =\; \backslash int\_\{-\backslash infty\}^\backslash infty\; F(t)\; G^*(t)\; \backslash ,\; dt$

where $F,G$ are the Fourier transforms of $f,g$.

At a first look, it seems to be a formula for functions only, but in fact in many cases it also works when $g$ is a distribution. Hence, by setting $$g(u)\; =\; \backslash sum\_\{n=1\}^\backslash infty\; \backslash Lambda(n)\; \backslash left[\; \backslash delta(u+\backslash ln\; n)\; +\; \backslash delta(u-\backslash ln\; n)\; \backslash right]\; ,$$ where $\backslash delta(u)$ is the Dirac delta, and carefully choosing a function $f$ and its Fourier transform, we get the formula above.

The Riemann zeta function can be replaced by a Dirichlet L-function of a Dirichlet character χ. The sum over prime powers then gets extra

factors of χ(p ^m), and the terms Φ(1) and Φ(0) disappear because the L-series has no poles.

More generally, the Riemann zeta function and the L-series can be replaced by the Dedekind zeta function of an algebraic number field or a Hecke L-series. The sum over primes then gets replaced by a sum over prime ideals.

Riemann's original use of the explicit formula was to give an exact formula for the number of primes less than a given number. To do this, take F(log(y)) to be y^1/2/log(y) for 0 ≤ y ≤ x and 0 elsewhere. Then the main term of the sum on the right is the number of primes less than x. The main term on the left is Φ(1); which turns out to be the dominant terms of the prime number theorem, and the main correction is the sum over non-trivial zeros of the zeta function. (There is a minor technical problem in using this case, in that the function F does not satisfy the smoothness condition.)

According to the Hilbert–Pólya conjecture, the complex zeroes ρ should be the eigenvalues of some linear operator T. The sum over the zeros of the explicit formula is then (at least formally) given by a trace:

:$\backslash sum\_\backslash rho\; F(\backslash rho)\; =\; \backslash operatorname\{Tr\}(F(\backslash widehat\; T\; )).\backslash !$

Development of the explicit formulae for a wide class of L-functions was given by {{harvtxt|Weil|1952}}, who first extended the idea to local zeta-functions, and formulated a version of a generalized Riemann hypothesis in this setting, as a positivity statement for a generalized function on a topological group. More recent work by Alain Connes has gone much further into the functional-analytic background, providing a trace formula the validity of which is equivalent to such a generalized Riemann hypothesis. A slightly different point of view was given by {{harvtxt|Meyer|2005}}, who derived the explicit formula of Weil via harmonic analysis on adelic spaces.

• Selberg trace formula
• Selberg zeta function

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{{reflist|25em}}

• {{Citation |author-link=Albert Ingham | last1=Ingham | first1=A.E. | title=The Distribution of Prime Numbers | publisher=Cambridge University Press | isbn=978-0-521-39789-6 | mr=1074573 | year=1990 | zbl=0715.11045 | edition=2nd |orig-date=1932 | series=Cambridge Tracts in Mathematics and Mathematical Physics | volume=30 | others=reissued with a foreword by R. C. Vaughan }}
• {{citation | last=Lang | first=Serge |author-link=Serge Lang | title=Algebraic number theory | edition=2nd | series=Graduate Texts in Mathematics | volume=110 | location=New York, NY | publisher=Springer-Verlag | year=1994 | isbn=0-387-94225-4 | zbl=0811.11001 }}
• {{Citation | last1=Riemann | first1=Bernhard | title=Ueber die Anzahl der Primzahlen unter einer gegebenen Grösse | url=http://www.maths.tcd.ie/pub/HistMath/People/Riemann/Zeta/ | year=1859 | journal=Monatsberichte der Berliner Akademie}}
• {{Citation | last1=Weil | first1=André | author1-link=André Weil | title=Sur les "formules explicites" de la théorie des nombres premiers | trans-title=On "explicit formulas" in the theory of prime numbers | mr=0053152 | year=1952 | journal=Comm. Sém. Math. Univ. Lund [Medd. Lunds Univ. Mat. Sem.] | volume=Tome Supplémentaire | pages=252–265 | zbl=0049.03205 | language=fr }}
• {{Citation | last1 = von Mangoldt | first1 = Hans | title=Zu Riemanns Abhandlung "Über die Anzahl der Primzahlen unter einer gegebenen Grösse" | journal = Journal für die reine und angewandte Mathematik | volume=114 | year=1895 | pages=255–305 | jfm=26.0215.03 | language=de | issn=0075-4102 | mr=1580379 | trans-title=On Riemann's paper "The number of prime numbers less than a given magnitude" }}
• {{Citation | last1 = Meyer | first1 = Ralf | title=On a representation of the idele class group related to primes and zeros of L-functions | journal = Duke Math. J. | volume=127 | number=3 | year=2005 | pages=519–595 | zbl=1079.11044 | issn=0012-7094 | doi=10.1215/s0012-7094-04-12734-4 | mr=2132868 | arxiv=math/0311468 | s2cid = 119176169 }}
• {{citation | last = Zagier | first = Don |author-link= Don Zagier | doi = 10.1007/bf03351556 | issue = S2 | journal = The Mathematical Intelligencer | pages = 7–19 | title = The first 50 million prime numbers | volume = 1 | year = 1977| s2cid = 37866599 }}

• {{citation | last=Edwards | first=H.M. |author-link=Harold Edwards (mathematician) | title=Riemann's zeta function | series=Pure and Applied Mathematics | volume=58 | location=New York-London |publisher=Academic Press | year=1974 | isbn=0-12-232750-0 | zbl=0315.10035 }}
• {{citation | last=Riesel | first=Hans |author-link=Hans Riesel | title=Prime numbers and computer methods for factorization | edition=2nd | series=Progress in Mathematics | volume=126 | location=Boston, MA | publisher=Birkhäuser | year=1994 | isbn=0-8176-3743-5 | zbl=0821.11001 }}

Category:Zeta and L-functions