{"docId":7663,"paperId":7663,"url":"https:\/\/hrj.episciences.org\/7663","doi":"10.46298\/hrj.2022.7663","journalName":"Hardy-Ramanujan Journal","issn":"","eissn":"2804-7370","volume":[{"vid":607,"name":"Volume 44 - Special Commemorative volume in honour of Srinivasa Ramanujan - 2021"}],"section":[],"repositoryName":"Hal","repositoryIdentifier":"hal-03251104","repositoryVersion":2,"repositoryLink":"https:\/\/hal.archives-ouvertes.fr\/hal-03251104v2","dateSubmitted":"2021-07-10 12:48:24","dateAccepted":"2022-01-09 20:11:10","datePublished":"2022-01-09 20:11:54","titles":{"en":"Proof of the functional equation for the Riemann zeta-function"},"authors":["Mehta, Jay","Zhu, P. -Y"],"abstracts":{"en":"In this article, we shall prove a result which enables us to transfer from finite to infinite Euler products. As an example, we give two new proofs of the infinite product for the sine function depending on certain decompositions. We shall then prove some equivalent expressions for the functional equation, i.e. the partial fraction expansion and the integral expression involving the generating function for Bernoulli numbers. The equivalence of the infinite product for the sine functions and the partial fraction expansion for the hyperbolic cotangent function leads to a new proof of the functional equation for the Riemann zeta function."},"keywords":["[MATH]Mathematics [math]"]}