Zeta constant
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In mathematics, a zeta constant is a number obtained by plugging an integer into the Riemann zeta function. This article provides a number of series identities for the zeta function for integer values.
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[edit] The Riemann zeta function at 0 and 1
At zero, one has
There is a pole at 1, so
[edit] Positive integers
[edit] Even positive integers
For the even positive integers, one has the well-known relationship to the Bernoulli numbers, given by Euler:
for . The first few values are given by
- ; the demonstration of this equality is known as the Basel problem.
The relationship between zeta at the positive even integers and the Bernoulli numbers may be written as
where An and Bn are integers for all even n. These are given by the integer sequences A046988 and A002432 in OEIS. Some of these values are reproduced below:
2n | A | B |
---|---|---|
2 | 6 | 1 |
4 | 90 | 1 |
6 | 945 | 1 |
8 | 9450 | 1 |
10 | 93555 | 1 |
12 | 638512875 | 691 |
14 | 18243225 | 2 |
16 | 325641566250 | 3617 |
18 | 38979295480125 | 43867 |
20 | 1531329465290625 | 174611 |
22 | 13447856940643125 | 155366 |
24 | 201919571963756521875 | 236364091 |
26 | 11094481976030578125 | 1315862 |
28 | 564653660170076273671875 | 6785560294 |
30 | 5660878804669082674070015625 | 6892673020804 |
32 | 62490220571022341207266406250 | 7709321041217 |
34 | 12130454581433748587292890625 | 151628697551 |
If we let ηn be the coefficient B / A as above,
then we find recursively,
This recurrence relation may be derived from that for the Bernoulli numbers.
[edit] Odd positive integers
For the first few odd natural numbers one has
- ; this is the harmonic series.
- ; this is called Apéry's constant
It is known that infinitely many of the numbers ζ(2n+1) (n ∈ N) are irrational. There are also results on the (ir)rationality of values of the Riemann zeta function at the elements of certain subsets of the positive odd integers. For example: At least one of ζ(5), ζ(7), ζ(9), or ζ(11) is irrational.
Most of the identities following below are provided by Simon Plouffe. They are notable in that they converge quite rapidly, giving almost three digits of precision per iteration, and are thus useful for high-precision calculations.
[edit] ζ(5)
Simon Plouffe gives the identities
and
[edit] ζ(7)
Note that the sum is in the form of the Lambert series.
[edit] ζ(2n+1)
By defining the quantities
a series of relationships can be given in the form
where An,Bn,Cn and Dn are positive integers. Plouffe gives a table of values:
n | A | B | C | D |
---|---|---|---|---|
3 | 180 | 7 | 360 | 0 |
5 | 1470 | 5 | 3024 | 84 |
7 | 56700 | 19 | 113400 | 0 |
9 | 18523890 | 625 | 37122624 | 74844 |
11 | 425675250 | 1453 | 851350500 | 0 |
13 | 257432175 | 89 | 514926720 | 62370 |
15 | 390769879500 | 13687 | 781539759000 | 0 |
17 | 1904417007743250 | 6758333 | 3808863131673600 | 29116187100 |
19 | 21438612514068750 | 7708537 | 42877225028137500 | 0 |
21 | 1881063815762259253125 | 68529640373 | 3762129424572110592000 | 1793047592085750 |
These integer constants may be expressed as sums over Bernoulli numbers, as given in (Vepstas, 2006) below.
[edit] Negative integers
In general, for negative integers, one has
for .
The so-called "trivial zeros" occur at the negative even integers:
The first few values for negative odd integers are
However, just like the Bernoulli numbers, these do not stay small for increasingly negative values. For details on the first value, see 1 + 2 + 3 + 4 + · · ·.
[edit] Derivatives
The derivative of the zeta function at the negative even integers is given by
The first few values of which are
One also has
and
where A is the Glaisher-Kinkelin constant.
[edit] References
- Simon Plouffe, "Identities inspired from Ramanujan Notebooks II", (1998).
- Linas Vepstas, "On Plouffe's Ramanujan Identities", ArXiv Math.NT/0609775 (2006).
- Wadim Zudilin, "One of the Numbers ζ(5), ζ(7), ζ(9), ζ(11) Is Irrational." Uspekhi Mat. Nauk 56, 149-150, 2001. PDF PS PDF Russian PS Russian