Vector potential and Riemannian space

Foundations of Physics 4 (1):137-147 (1974)
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Abstract

This paper uncovers the basic reason for the mysterious change of sign from plus to minus in the fourth coordinate of nature's Pythagorean law, usually accepted on empirical grounds, although it destroys the rational basis of a Riemannian geometry. Here we assume a genuine, positive-definite Riemannian space and an action principle which is quadratic in the curvature quantities (and thus scale invariant). The constant σ between the two basic invariants is equated to1/2. Then the matter tensor has the trace zero. In consequence of the constancy of the scalar curvature and the divergence identity of the matter tensor, the perturbation metric has to satisfy a scalar and a vector condition, with a negative sign in the fourth coordinate. These conditions lead to the Lorentz condition and the wave equation for the vector potential. Thus the entire Maxwell-Lorentz type of electrodynamics becomes logically derivable, making no concession to any irrationality

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10.1007/bf00708564

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Gravitation and Riemannian space.C. Lanczos - 1975 - Foundations of Physics 5 (1):9-18.

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Vector potential and quadratic action.C. Lanczos - 1972 - Foundations of Physics 2 (4):271-285.

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