English

Bernoulli Operator and Riemann's Zeta Function

Number Theory 2015-09-03 v7 Complex Variables

Abstract

We introduce a Bernoulli operator,let B\mathbf{B} denote the operator symbol,for n=0,1,2,3,... let Bn:=Bn{\mathbf{B}^n}: = {B_n} (where Bn{B_n} are Bernoulli numbers,B0=1,B1=1/2,B2=1/6,B3=0{B_0} = 1,B{}_1 = 1/2,{B_2} = 1/6,{B_3} = 0...).We obtain some formulas for Riemann's Zeta function,Euler constant and a number-theoretic function relate to Bernoulli operator.For example,we show that B1s=ζ(s)(s1),{\mathbf{B}^{1 - s}} = \zeta (s)(s - 1), γ=logB,\gamma = - \log \mathbf{B},where γ{\gamma} is Euler constant.Moreover,we obtain an analogue of the Riemann Hypothesis (All zeros of the function ξ(B+s)\xi (\mathbf{B} + s) lie on the imaginary axis).This hypothesis can be generalized to Dirichlet L-functions,Dedekind Zeta function,etc.In particular,we obtain an analogue of Hardy's theorem(The function ξ(B+s)\xi (\mathbf{B} + s) has infinitely many zeros on the imaginary axis). \par In addition,we obtain a functional equation of logΠ(Bs)\log \Pi (\mathbf{B}s) and a functional equation of logζ(B+s)\log \zeta (\mathbf{B} + s) by using Bernoulli operator.

Keywords

Cite

@article{arxiv.1011.3352,
  title  = {Bernoulli Operator and Riemann's Zeta Function},
  author = {Yiping Yu},
  journal= {arXiv preprint arXiv:1011.3352},
  year   = {2015}
}
R2 v1 2026-06-21T16:43:50.192Z