Sources for gravity. The Noetherian field theories
Christian Fr{\o}nsdal

TL;DR
This paper explores the correct sources for Einstein's field equations, emphasizing Noetherian field theories and their relation to hydrodynamics, gravity, and particle physics, highlighting the role of gauge theories and permittivities.
Contribution
It identifies a class of Noetherian field theories as sources for Einstein's equations, linking hydrodynamics with general relativity through an action principle and gauge theory insights.
Findings
The 2-form gauge theory of Ogievetskij and Polubarinov is crucial for gravity sources.
Permittivities have multiple unexpected roles in the theory.
A unique relativistic hydrodynamics with vorticity and continuity equations is developed.
Abstract
This paper attempts to throw some light on what is the correct choice of sources for Einstein's field equations for the gravitational metric, and on the definition of the Cauchy-Noether energy-momentum tensor of relativistic field theories, the natural source of Einstein's equation. The paper opens with a brief review of the development of an idea first advanced by Maupertui (1741): the Dynamical Action Principle. The story reached a turning point with the creation of Einstein's theory of General Relativity. The associated work of Noether served as an inspiration for particle physics for 100 years. The discovery of gravity waves (LIGO 2016) showed that Gravity is a phenomenon akin to, and part of, particle physics, to be treated as a canonical field theory, and eventually quantized. Here the subject is the theory of the classical metric field in interaction with extended distributions…
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Taxonomy
TopicsCosmology and Gravitation Theories · Geophysics and Gravity Measurements · Relativity and Gravitational Theory
