Critical Line in the Euler–riemann Zeta Function

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Annals of Mathematics and Physics volume8-issue2 articles
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Submitted: March 24, 2025
Published: Apr 1, 2025
DOI: 10.17352/amp.000146
Keywords:
Euler, Riemann, Zeta function

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Frank Trefoily*
Faculty of Medicine, Masaryk University, Brno, Czech Republic

Abstract

Abstract


This study focused on the transformation of an exponentially growing divergent function sin(Rln(x)) into a convergent function by its complementary exponential function xt in such a manner that the sizes of positive and negative areas under sin would be the same. The transformation will provide the entire sin function with self-compensatory behavior. The exponent's value was computed and found to be -1/2, which is the only exponent, which lets entire product of the function converge to zero (sum of area for positive real numbers and sum of products for natural numbers). The exponent -1/2 is algebraically and geometrically inevitable for the function xtsin(Rln(x)) converging to zero. This result directly impacts the position of the critical line in the Euler-Riemann zeta function.

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Article Details

Frank Trefoily*. (2025). Critical Line in the Euler–riemann Zeta Function. Annals of Mathematics and Physics, 8(2), 057–059. https://doi.org/10.17352/amp.000146
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Copyright (c) 2025 Trefoily F.

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