Prove that the real part of this limit converges to $\frac{1}{2}$

Question

Let $s= 1/3 + 14i$. Prove that the real part of this limit converges to $\frac{1}{2}$:
$$ \Re\lim_{n \rightarrow \infty} \left( \left[ 1- \left( \sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{\zeta(\tfrac{k}{n}+s)} \Bigg/ \sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{\zeta(\tfrac{k}{n}+s+\tfrac{1}{n})} \right) \right]^{-1} +\frac1n + s \right) = \frac{1}{2}. $$ Mathematica 8.0.1:

n = 100;
s = (1/3 + 14*I);
s + 1/n + 
  1/(1 - Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/Zeta[s + k/n], {k, 1,
         n}]/Sum[(-1)^(k - 1)*
        Binomial[n - 1, k - 1]/Zeta[s + k/n + 1/n], {k, 1, n}]);
N[%, n]

Output:
0.50000000000000000000000000000000000000000000000000000000000000000000
000000000000000000000000000000 +
14.134725141734693790457251983562470270784257115699243175685567460149\ 96342980925676494901039317156101 I

Pari GP:

n = 30
s = (1/3 + 14*I)
s + 1/n + 1/(1 - sum (k = 1, n, (-1)^(k - 1)*binomial(n - 1, k - 1)/zeta (s + k/n))/sum (k = 1, n, (-1)^(k - 1)*binomial(n - 1, k - 1)/zeta (s + k/n + 1/n)))

Copy Paste via mouse button and press Shift Enter in Pari GP to compute.
The working precision in Pari GP is not as good as in Mathematica. Therefore $n=30$ instead of $n=100$.

Answer 1

Let: $$f(x)=\zeta (x)$$ $$A(n,s)=\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}-\frac{1}{n}+s\right)}$$ $$B(n,s)=\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}+s\right)}$$ $$X(n,s)=\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}-\frac{1}{n}-s\right)}$$ $$Y(n,s)=\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}-s\right)}$$ $$a=\frac{1}{1-\frac{A(n,s)}{B(n,s)}}+s$$ $$b=\frac{1}{1-\frac{B(n,s)}{A(n,s)}}-s$$ $$c=\frac{1}{1-\frac{X(n,s)}{Y(n,s)}}-s$$ Notice that: $$X(n,s)=A(n,-s)$$
and
$$Y(n,s)=B(n,-s)$$

For $s=1/3+14i$, show: $$\lim_{n\to \infty } \, ((a+b)(1-(b-c)))=1$$ Leaving out the limit symbol and substituting $a,b,c$: $$\left(\frac{1}{1-\frac{A}{B}}+\frac{1}{1-\frac{B}{A}}\right) \left(-\frac{1}{1-\frac{B}{A}}+\frac{1}{1-\frac{X}{Y}}+1\right)=1$$ which is equal to: $$-\frac{A Y+B X-2 B Y}{(A-B) (X-Y)}=1$$ multiplying with the denominator: $$-A Y-B X+2 B Y=(A-B) (X-Y)$$ subtracting with the right hand side: $$-A Y-B X+2 B Y -(A-B) (X-Y)=0$$ factoring: $$B Y-A X=0$$ which is: $$A X=B Y$$ Including the limit symbol again and substituting $A,B,X,Y$: $$\lim_{n\to \infty } \, \left(\left(\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}-\frac{1}{n}+s\right)}\right) \sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}-\frac{1}{n}-s\right)}=\left(\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}+s\right)}\right) \sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{f\left(\frac{k}{n}-s\right)}\right)$$ For $n=30$ and $s=1/3+14i$ we get numerically:
for the left hand side:
$$55226.0411027488837442269063281-14296.8517199926101555805382701 i$$ and for the right hand side:
$$55226.0411027488837442269063281-14296.8517199926101555805382701 i$$ which appear close to each other.

---

while for example if we set the function to $f(x)=\zeta \left(x,\frac{1}{3}\right)$ we get numerically,
for the left hand side: $$-\text{5.7804095358568700751853287633386056719879460800172587438796357645$\grave{ }$30.044170983082427*${}^{\wedge}$-32}-\text{4.5948958062512910951997009159524637155472195553235558338875204958$\grave{ }$29.944488042052914*${}^{\wedge}$-32} i$$ and for the right hand side:
$$-\text{8.1747358863640979486289267057810389747002120618563412538892819063$\grave{ }$30.082847849900105*${}^{\wedge}$-32}-\text{4.9430723869496501619456415921898782802016090061312604239413643251$\grave{ }$29.864371090122273*${}^{\wedge}$-32} i$$ which are different.

Mathematica:

Clear[f, A, B, n, s, a, b, x, m];
f[x_] := Zeta[x];
A[n_, s_] := 
 Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[s + k/n - 1/n], {k, 1, n}]
B[n_, s_] := 
 Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[s + k/n], {k, 1, n}]
X[n_, s_] := 
 Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[-s + k/n - 1/n], {k, 1, n}]
Y[n_, s_] := 
 Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[-s + k/n], {k, 1, n}]

n = 30;
s = 1/3 + 14*I;
N[A[n, s]*X[n, s], 30]
N[B[n, s]*Y[n, s], 30]

Mathematica again:

Clear[f, A, B, n, s, a, b, x, m];
f[x_] = Zeta[x];
A[n_, s_] = 
  Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[s + k/n - 1/n], {k, 1, n}];
B[n_, s_] = 
  Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[s + k/n], {k, 1, n}];
X[n_, s_] = 
  Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[-s + k/n - 1/n], {k, 1, 
    n}];
Y[n_, s_] = 
  Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/f[-s + k/n], {k, 1, n}];
n = 120;
s = N[1 + 2*I , 200];
Block[{$MaxExtraPrecision = 600}, N[A[n, s]*X[n, s]/(B[n, s]*Y[n, s]), 20]]
N[1 + 5/((s/I)^2 + 4), 20]

which numerically suggests that:

$$\lim_{n\to \infty } \, \left(\frac{A(n,s) X(n,s)}{B(n,s) Y(n,s)} \right) =1+\frac{5}{4+\left(\frac{s}{i}\right)^2} $$ for those $s$ closest to the first trivial zero.

Answer 2

The limit in the question above can be found by simplifying ratios of consecutive repeated derivatives of $\frac{1}{\zeta(s)}$.

---

My recent thoughts:

See: https://mathoverflow.net/a/439430/25104

Let: $$\rho=\frac{1}{1-\frac{A}{B}}+\frac{1}{n}+s$$

Then according to Mathematica 8.0.1 the following:

$$\tag{1}$$ $$\text{Reduce}\left[\rho=\frac{1}{1-\frac{A}{B}}+\frac{1}{n}+s\land \frac{1}{1-\frac{A}{B}}+\frac{1}{n}+s=\left(-s+\frac{1}{1-\frac{B}{A}}-\frac{1}{n}\right)^*\land B\neq 0\land \Re(\rho)\geq 0\land \Re(\rho)\leq 1,\Re(\rho)\right]$$

reduces to the conditions:

$$\tag{2}$$ $A=\frac{B \cdot n \cdot \rho -B \cdot n \cdot s+B (-(n+1))}{n \cdot \rho-n \cdot s-1}$ $\land \left(\left(\Im(\rho)<\Im(s)\land \Re(\rho)=\frac{1}{2}\land (\Re(B)<0\lor (\Re(B)=0\land (\Im(B)<0\lor \Im(B)>0))\lor \Re(B)>0)\right)\lor \left(\Im(\rho)=\Im(s)\land \left(\left(\Re(s)<\frac{n-2}{2 n}\land \Re(\rho)=\frac{1}{2}\land (\Re(B)<0\lor (\Re(B)=0\land (\Im(B)<0\lor \Im(B)>0))\lor \Re(B)>0)\right)\lor \left(\Re(s)>\frac{n-2}{2 n}\land \Re(\rho)=\frac{1}{2}\land (\Re(B)<0\lor (\Re(B)=0\land (\Im(B)<0\lor \Im(B)>0))\lor \Re(B)>0)\right)\right)\right)\lor \left(\Im(\rho)>\Im(s)\land \Re(\rho)=\frac{1}{2}\land (\Re(B)<0\lor (\Re(B)=0\land (\Im(B)<0\lor \Im(B)>0))\lor \Re(B)>0)\right)\right)\land 0\leq \Re(\rho)\leq 1$

So in other words there are choices of $A$, $B$ and the starting point $s$ where $\Re(\rho) = 1/2$, but the conditions above must be satisfied in order for the following equation:

$$\lim_{n \rightarrow \infty}\left( \frac{1}{1-\frac{A}{B}}+\frac{1}{n}+s=\left(-s+\frac{1}{1-\frac{B}{A}}-\frac{1}{n}\right)^*\right)$$

to be true.

In the case of the Riemann zeta function we would write:

$$A=\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{\zeta \left(\frac{k}{n}+s\right)} \tag{3}$$

$$B=\sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{\zeta \left(\frac{k}{n}+s+\frac{1}{n}\right)} \tag{4}$$

The parentheses with the star:
$$\left(\right)^*$$ is the complex conjugate.

How to show this in the case of the Riemann zeta function I don't know.

Demonstration in Mathematica 8.0.1:

(* Mathematica start *)
Clear[A, B, n, k, s];
n = 20;
s = 0;
A = Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/Zeta[s + k/n], {k, 1, n}];
B = Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/Zeta[s + k/n + 1/n], {k, 
    1, n}];
"The first trivial zero with the zero of the conjugated limit shifted \
by 1 and with opposite sign:"
Conjugate[-s - 1/n + 1/(1 - B/A)];
N[%, n]
 s + 1/n + 1/(1 - A/B);
N[%, n]

Clear[A, B, n, k, s];
n = 20;
s = (1/3 + 14*I);
A = Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/Zeta[s + k/n], {k, 1, n}];
B = Sum[(-1)^(k - 1)*Binomial[n - 1, k - 1]/Zeta[s + k/n + 1/n], {k, 
    1, n}];
"The first non-trivial zero:"
Conjugate[-s - 1/n + 1/(1 - B/A)];
N[%, n]
 s + 1/n + 1/(1 - A/B);
N[%, n]

"The conditions to be proven for the case of the Riemann zeta function:"
Clear[s, A, B, n, z, k];
n = 19;
Reduce[rho == s + 1/n + 1/(1 - A/B) && 
  s + 1/n + 1/(1 - A/B) == Conjugate[-s - 1/n + 1/(1 - B/A)] && 
  B != 0 && Re[rho] >= 0 && Re[rho] <= 1, Re[rho]]
(*end*)

Answer 3

The starting point for deriving the formula in the question is the following limits for the derivatives of the Riemann zeta function:

$$\zeta '(s)=\lim_{c\to 1} \, \zeta (s) \left(\zeta (c)-\frac{\zeta (c) \zeta (s)}{\zeta (c+s-1)}\right)$$

$$\zeta ''(s)=\lim_{c\to 1} \, \zeta '(s) \left(\zeta (c)-\frac{\zeta (c) \zeta '(s)}{\zeta '(c+s-1)}\right)$$

$$\zeta ^{(3)}(s)=\lim_{c\to 1} \, \zeta ''(s) \left(\zeta (c)-\frac{\zeta (c) \zeta ''(s)}{\zeta ''(c+s-1)}\right)$$

$$\zeta ^{(4)}(s)=\lim_{c\to 1} \, \zeta ^{(3)}(s) \left(\zeta (c)-\frac{\zeta (c) \zeta ^{(3)}(s)}{\zeta ^{(3)}(c+s-1)}\right)$$

$$\zeta ^{(5)}(s)=\lim_{c\to 1} \, \zeta ^{(4)}(s) \left(\zeta (c)-\frac{\zeta (c) \zeta ^{(4)}(s)}{\zeta ^{(4)}(c+s-1)}\right)$$

$$\zeta ^{(6)}(s)=\lim_{c\to 1} \, \zeta ^{(5)}(s) \left(\zeta (c)-\frac{\zeta (c) \zeta ^{(5)}(s)}{\zeta ^{(5)}(c+s-1)}\right)$$

$$\vdots$$

$$\zeta ^{(n+1)}(s)=\lim_{c\to 1} \, \zeta ^{(n)}(s) \left(\zeta (c)-\frac{\zeta (c) \zeta ^{(n)}(s)}{\zeta ^{(n)}(c+s-1)}\right)$$

In mathematica this would be:

Clear[s, c]
Limit[((-Zeta[s]*Zeta[c]/Zeta[s + c - 1] + Zeta[c])*Zeta[s]), c -> 1]
Limit[((-Zeta'[s]*Zeta[c]/Zeta'[s + c - 1] + Zeta[c])*Zeta'[s]), c -> 1]
Limit[((-Zeta''[s]*Zeta[c]/Zeta''[s + c - 1] + Zeta[c])*Zeta''[s]), c -> 1]
Limit[((-Zeta'''[s]*Zeta[c]/Zeta'''[s + c - 1] + Zeta[c])*Zeta'''[s]), c -> 1]
Limit[((-Zeta''''[s]*Zeta[c]/Zeta''''[s + c - 1] + Zeta[c])*Zeta''''[s]), c -> 1]
Limit[((-Zeta'''''[s]*Zeta[c]/Zeta'''''[s + c - 1] + Zeta[c])*Zeta'''''[s]), c -> 1]

It is known that the ratios of consecutive derivatives a function in general converges to the nearest root (or singularity).

So: $$\lim\limits_{n \rightarrow \infty} \frac{\zeta ^{(n+1)}(s)}{\zeta ^{(n)}(s)} + s = \text{nearest zero of the Riemann zeta function}$$

By succesively substituting the right hand side of the lower order derivatives of Riemann zeta into the right hand side of the immediate higher order derivative of Riemann zeta, with the help of the following Mathematica program;

Clear[s, c, A]
A0 = 1/Zeta[s];
Limit[Zeta[c] A0 - Zeta[c]/Zeta[-1 + c + s], c -> 1];

A1 = Zeta[c]/Zeta[-0 + 0 c + s] - Zeta[c]/Zeta[-1 + 1 c + s];
A2 = Zeta[c]/Zeta[-1 + 1 c + s] - Zeta[c]/Zeta[-2 + 2 c + s];
A3 = Zeta[c]/Zeta[-2 + 2 c + s] - Zeta[c]/Zeta[-3 + 3 c + s];
A4 = Zeta[c]/Zeta[-3 + 3 c + s] - Zeta[c]/Zeta[-4 + 4 c + s];
A5 = Zeta[c]/Zeta[-4 + 4 c + s] - Zeta[c]/Zeta[-5 + 5 c + s];

B1 = ReplaceAll[A1, Zeta[-1 + 1 c + s] -> 1/A2];
B2 = ReplaceAll[B1, Zeta[-0 + 0 c + s] -> 1/A1];

C1 = ReplaceAll[B2, Zeta[-2 + 2 c + s] -> 1/A3];
C2 = ReplaceAll[C1, Zeta[-1 + 1 c + s] -> 1/A2];
C3 = ReplaceAll[C2, Zeta[-0 + 0 c + s] -> 1/A1];

D1 = ReplaceAll[C3, Zeta[-3 + 3 c + s] -> 1/A4];
D2 = ReplaceAll[D1, Zeta[-2 + 2 c + s] -> 1/A3];
D3 = ReplaceAll[D2, Zeta[-1 + 1 c + s] -> 1/A2];
D4 = ReplaceAll[D3, Zeta[-0 + 0 c + s] -> 1/A1];

E1 = ReplaceAll[D4, Zeta[-4 + 4 c + s] -> 1/A5];
E2 = ReplaceAll[E1, Zeta[-3 + 3 c + s] -> 1/A4];
E3 = ReplaceAll[E2, Zeta[-2 + 2 c + s] -> 1/A3];
E4 = ReplaceAll[E3, Zeta[-1 + 1 c + s] -> 1/A2];
E5 = ReplaceAll[E4, Zeta[-0 + 0 c + s] -> 1/A1];

FullSimplify[A0]
FullSimplify[A1]
FullSimplify[B2]
FullSimplify[C3]
FullSimplify[D4]
FullSimplify[E5]

one gets:

FullSimplify[A0] $$\frac{1}{\zeta (s)}$$ FullSimplify[A1] $$\zeta (c) \left(\frac{1}{\zeta (s)}-\frac{1}{\zeta (c+s-1)}\right)$$ FullSimplify[A2] $$\zeta (c)^2 \left(\frac{1}{\zeta (s)}-\frac{2}{\zeta (c+s-1)}+\frac{1}{\zeta (2 c+s-2)}\right)$$ FullSimplify[A3] $$\zeta (c)^3 \left(\frac{1}{\zeta (s)}-\frac{3}{\zeta (c+s-1)}+\frac{3}{\zeta (2 c+s-2)}-\frac{1}{\zeta (3 c+s-3)}\right)$$ FullSimplify[A4] $$\zeta (c)^4 \left(\frac{1}{\zeta (s)}-\frac{4}{\zeta (c+s-1)}+\frac{6}{\zeta (2 c+s-2)}-\frac{4}{\zeta (3 c+s-3)}+\frac{1}{\zeta (4 c+s-4)}\right)$$ FullSimplify[A5] $$\zeta (c)^5 \left(\frac{1}{\zeta (s)}-\frac{5}{\zeta (c+s-1)}+\frac{10}{\zeta (2 c+s-2)}-\frac{10}{\zeta (3 c+s-3)}+\frac{5}{\zeta (4 c+s-4)}-\frac{1}{\zeta (5 c+s-5)}\right)$$

That looks like the binomial coefficients, and should be because of the binary(?) substition.

Imitating the last formula:

Clear[n, k, c, h, s]
n = 6;
Table[(-1)^(k + 1)*
  Binomial[n - 1, k - 1]/Zeta[-(k - 1) + (k - 1) c + s], {k, 1, n}]

So:

$$\frac{\zeta (c)^{n-1} \sum _{k=1}^n \frac{(-1)^{k+1} \binom{n-1}{k-1}}{\zeta (c (k-1)-(k-1)+s)}}{\zeta (c)^{n+1-1} \sum _{k=1}^{n+1} \frac{(-1)^{k+1} \binom{n+1-1}{k-1}}{\zeta (c (k-1)-(k-1)+s)}} \tag{1}$$

One can strike out part of the binomials to get the $\frac{A}{B}$ formula in the question.

How ever, in order to not lose information, one sets $c \rightarrow 1+\frac{1}{h}$

Because both $n \rightarrow \infty$ and $h \rightarrow \infty$ and we want to have a formula with as few variables as possible, we simply replace $h$ with $n$ (that is, $h=n$ from now on, because we say so). So:

$$c=1+\frac{1}{n}$$

close to $c=1$: $\zeta (c) \approx \frac{1}{c-1}$

introducing these changes, except striking out binomials, into $(1)$ we get:

$$\frac{\sum _{k=1}^n \frac{(-1)^{k+1} \binom{n-1}{k-1}}{\zeta \left(\frac{k-1}{n}+s\right)}}{\zeta \left(1+\frac{1}{n}\right) \left(\sum _{k=1}^{n+1} \frac{(-1)^{k+1} \binom{n}{k-1}}{\zeta \left(\frac{k-1}{n}+s\right)}\right)}$$

Striking out binomials we get:

$$\Re\lim_{n \rightarrow \infty} \left( \left[ 1- \left( \sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{\zeta(\tfrac{k}{n}+s)} \Bigg/ \sum _{k=1}^n \frac{(-1)^{k-1} \binom{n-1}{k-1}}{\zeta(\tfrac{k}{n}+s+\tfrac{1}{n})} \right) \right]^{-1} \underset{\text{conjectured guesses}}{\underbrace{+\frac1n + s}} \right) = \frac{1}{2}.$$

with conjectured terms $$+\frac1n + s$$ that are guesses to make it work.

We now have the formula in the form:

$$\rho=\frac{1}{1-\frac{A}{B}}+\frac{1}{n}+s$$

Please go to the previous comment as an answer: https://mathoverflow.net/a/377346/25104

Answer 4

It appears that we don't need analytic continuation to locate the first non-trivial Riemann zeta zero:

(*start*)
(*Mathematica 8.0.1*)
n = 100;(*set n=200 for more digits*)
s = (3/2 + 14*I);
s + 1/n + 
  1/(1 - Sum[(-1)^(k - 1)*
        Binomial[n - 1, k - 1]/HarmonicNumber[10^10000, s + k/n], {k, 
        1, n}]/Sum[(-1)^(k - 1)*
        Binomial[n - 1, k - 1]/
         HarmonicNumber[10^10000, s + k/n + 1/n], {k, 1, n}]);
N[%, n]
(*end*)

Output:

0.49999999999999999999999999999999999999999999999999999999999999999999\
821263876336076842104900392907 + 
 14.134725141734693790457251983562470270784257115699243175685567460149\
95997175784113908425467589217131 I