A dynamical approach to general relativity based on proper time

This work places the invariant ¿¿2 at the center of the gravitational interaction, interpreting it not as a purely geometric object but as the differential of proper time, endowed with direct physical meaning. Starting from the extension of Fermat’s principle to massive particles—namely, the require...

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Detalles Bibliográficos
Autor: Haro Cases, Jaume|||0000-0002-5705-2405
Tipo de recurso: artículo
Fecha de publicación:2026
País:España
Institución:Universitat Politècnica de Catalunya (UPC)
Repositorio:UPCommons. Portal del coneixement obert de la UPC
Idioma:inglés
OAI Identifier:oai:dnet:upcommonspor::f5ee9b7032cdcf45128e9d63a240e557
Acceso en línea:https://hdl.handle.net/2117/460874
https://dx.doi.org/10.3390/universe12030079
Access Level:acceso abierto
Palabra clave:General relativity
Equivalence principle
Newtonian gravity
Àrees temàtiques de la UPC::Física::Astronomia i astrofísica
Descripción
Sumario:This work places the invariant ¿¿2 at the center of the gravitational interaction, interpreting it not as a purely geometric object but as the differential of proper time, endowed with direct physical meaning. Starting from the extension of Fermat’s principle to massive particles—namely, the requirement that freely falling bodies follow trajectories that extremize proper time, which for timelike motion corresponds to a local maximum—and invoking the universality of Galilean free fall, we derive the form of ¿¿2 in a static gravitational field. Lorentz invariance then provides the natural framework to extend this result to systems involving moving matter. The invariant derived through this procedure matches the weak-field limit of General Relativity formulated in the harmonic gauge. Within this linearized regime, we show that the structure of the theory already contains the seeds of its nonlinear completion: any dynamically consistent extension to strong gravitational fields necessarily involves the Ricci tensor. From this viewpoint, Einstein’s field equations appear not as a postulated geometric law but as the unique covariant closure required to ensure energy–momentum conservation and the self-consistency of the gravitational interaction