Non-local gravitational self-energy induces spontaneous wave-function collapse with a model-independent collapse time inversely proportional to system mass.
Geodesic completeness from string T-duality,
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Regularizing the Aichelburg-Sexl metric for entangled photons produces a zero-throat wormhole geometry realizing ER=EPR, with gravitational self-energy scaling as 4G(ℏω)²/(c⁴L) ln(d²/l₀²) and matching an entanglement-entropy calculation.
Incorporating non-local gravitational self-energy from a T-duality-inspired model yields a regular neutral black-hole metric with extremal Planck-mass particle-black-hole solutions that are thermodynamically stable and suggested as dark matter.
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Spontaneous wave function collapse from non-local gravitational self-energy
Non-local gravitational self-energy induces spontaneous wave-function collapse with a model-independent collapse time inversely proportional to system mass.
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Regular black holes with gravitational self-energy as dark matter
Incorporating non-local gravitational self-energy from a T-duality-inspired model yields a regular neutral black-hole metric with extremal Planck-mass particle-black-hole solutions that are thermodynamically stable and suggested as dark matter.