Time Conservation Principle versus Energy Physics

Authors: Iyer R*

DOI: 10.23880/oaja-16000139

Volume 2, Issue 2

Abstract

This article explores the conservation principles that may apply to time, contrasting them with the well-established conservation of energy. Publications of peer reviewed papers enabled the author to derive time to be a tensor, algebraic than merely arithmetic scalar. Here, these are brought out in a dramatic manner to highlight gradation of high rank tensors, which decompose to multiple vectors. This study reexamines time originally as potentially the most conserved attribute in physics, considering the quantum nature of well-known established by thermodynamic fundamentalistic energy conservation. Literature surveys quoting time conservation versus energy physics studies, especially quantum gravity, Page–Wootters formalism, and related areas with concept of time as emergent and travel phenomena associated to time as a wavefunction tensor have been highlighted. Mathematical theory derivations showing conservation of time principle with tensor analysis giving key equations and establishing time invariance with point in space via differential testing in relation to domains of reality of time tensor, = constant proves that conservation of time applies like the general principle of energy quantum conservation well within given conditions. Quantified clocks applying time conservation principle analyze strong gravity versus weak gravity environments like microblackholes and the zero-point fields, showing how branes may produce curled up dimensions, like Kaluza-Klein 5D curled up dimensions. Verifications with experimental methods, especially testing time conservation potentially would uncover new fundamental principles of physics - time conservation principle after establishment will propel to revolutionize our understanding of the universe and drive innovation in both theoretical and applied physics, specifically quantum technologies and astrophysical endeavors, especially measurement techniques with LHC, for example have been considered to launch research efforts of the future.

Keywords: Time Conservation; Energy Physics; Page-Wootters Formalism; Quantum Technologies; Astrophysical Endeavors

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