Quantum Properties and Gravitational Field of a Proper Time Oscillator
Hou Y. Yau
TL;DR
This paper explores a proper time oscillator as a zero-spin bosonic field, showing it can mimic a point mass in general relativity and produce a Schwarzschild spacetime outside.
Contribution
It introduces the concept of a proper time oscillator as a quantum field with gravitational properties, linking quantum oscillations to classical gravitational solutions.
Findings
Proper time oscillators behave as zero-spin bosonic fields.
A proper time oscillator can mimic a point mass in general relativity.
The external spacetime is described by the Schwarzschild solution.
Abstract
We find that a field with oscillations of matter in proper time has the properties of a zero-spin bosonic field. A particle observed in this field is a proper time oscillator. Neglecting all quantum effects, a proper time oscillator can mimic a point mass at rest in general relativity. The spacetime outside a 'stationary' proper time oscillator is a Schwarzschild field.
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Taxonomy
TopicsRelativity and Gravitational Theory · Quantum Mechanics and Applications · Cosmology and Gravitation Theories