This record is part of the Mass, Proper Time, and Gravity series. Full series community: https: //zenodo. org/communities/mass-proper-time-gravity/ The previous papers in this series proposed a geometric-informational reading of relativity, in which proper time is interpreted as the rhythm or phase accumulation of physical processes, invariant mass as the total energy of a system in its centre-of-momentum frame divided by c², and gravity as the metric response to energy-momentum content. This Part III strengthens the notion of physical configuration for many-particle matter. In fermionic matter, the configuration is not merely a spatial arrangement, but an organized occupation of quantum states. Because electrons are fermions, the Pauli exclusion principle constrains this occupation; under compression it forces electrons into higher-momentum states, producing Fermi energy and degeneracy pressure. This pressure is part of the energy-momentum tensor and thus contributes to the geometry produced by the object. White dwarfs provide an operational test: a simple zero-temperature mass-radius relation reproduces the radii of nearby white dwarfs (40 Eridani B, Sirius B, Procyon B, Stein 2051 B) at the few-percent level. No new equation and no new empirical prediction are proposed; the contribution is a conceptual synthesis, in which the macroscopic gravitational structure of a compact object is read as a trace of the microscopic organization of quantum states. An outlook section discusses the relation to the causal-counting bridge of Part II and to holography, and explicitly states that this does not constitute a theory of quantum gravity but only indicates the kind of bridge such a theory may require.
Olivian Barbu (Tue,) studied this question.