What question did this study set out to answer?

The aim is to derive the tensor sector of gravity from the Vacuum Folding Dynamics framework, closing a conceptual gap in understanding gravitational interactions.

April 10, 2026Open Access

Emergent Tensor Gravity from Vacuum Entanglement Scattering

Key Points

The aim is to derive the tensor sector of gravity from the Vacuum Folding Dynamics framework, closing a conceptual gap in understanding gravitational interactions.
Developed a framework using vacuum micro-state density to model gravity through a scalar field.
Applied the Clausius relation to local Rindler horizons and used the Raychaudhuri equation to bridge geometric concepts.
Analyzed consistency between different theoretical routes to validate the effective gravitational constant.
Successfully derived a complete Einstein equation incorporating tensor structures.
Demonstrated that the effective gravitational constant equals Newton's gravitational constant universally.
Identified conditions under which scalar field contributions align with tensor sector explanations.

Abstract

The Vacuum Folding Dynamics (VFD) framework models gravity through a scalar field σf representing the vacuum micro-state density. Paper A established a Le Sage overpressure mechanism in which isotropic vacuum flux, partially attenuated by matter, reproduces Newton's constant through a self-consistency condition. That derivation assumes the full-gravity interpretation but does not derive the spin-2 (tensor) sector that carries ~99. 9999999% of the gravitational interaction. This paper closes that gap. We show that the VFD entanglement entropy sₕol = kB c₀ (σf/σ₀) ^2/3 / lP² (Paper VII) provides the area-scaling input required by the Jacobson (1995) thermodynamic construction. Applying the Clausius relation δQ = TU dS to local Rindler horizons, combined with the Raychaudhuri equation as a geometric bridge, yields the full Einstein equation G⏛⏜ + Λ g⏛⏜ = (8π GN / c⁴) T⏛⏜ — including the complete tensor structure — with an effective gravitational constant Gₑff = GN / (4 c₀). Consistency between the Le Sage route (Paper A, constraining the scalar mass m_σ) and the Jacobson route (constraining the boundary-mode fraction c₀) requires c₀ = 1/4, yielding Gₑff = GN exactly. In the Le Sage overpressure picture, the scalar field satisfies δσf/σ₀ < 10^-260 everywhere, so Gₑff = GN universally — not only in the weak-field limit. The Susskind-Uglum (SU) mechanism is extended to VFD's Brans-Dicke action at the equilibrium point Φ₀ = 1, providing independent UV support for c₀ = 1/4 at Level 3. The scalar-only interpretation — in which the Le Sage mechanism generates only α² GN — destroys the constant product α · λC = 3. 59 μm, leaves the tensor sector unexplained, and eliminates VFD's main experimental signature. An exponent error in Paper A §8. 1 is corrected. Eight open problems are catalogued. The paper rests on two assumptions beyond established physics: (1) the VFD micro-state Hilbert space (Paper VII), and (2) the Clausius relation on local Rindler horizons (Jacobson 1995).

Read Full Paperexternally

Bookmark

View Full Paper

Cite This Study

Daniel Leonforte (Fri,) studied this question.

synapsesocial.com/papers/69d893626c1944d70ce04657 https://doi.org/https://doi.org/10.5281/zenodo.19452426

Bookmark

View Full Paper