What question did this study set out to answer?

The aim is to explore how catalyzed vacuum transitions can detect scalar fields without relying on parametric amplification.

March 18, 2026Open Access

Stochastic Resonance and Catalyzed Vacuum Transitions: Beyond Parametric Amplification

Key Points

The aim is to explore how catalyzed vacuum transitions can detect scalar fields without relying on parametric amplification.
Derived Kramers escape rate related to vacuum transitions.
Examined stochastic resonance enhancement in Casimir metamaterials.
Identified nucleation barrier scaling as key experimental question.
Established a connection between scalar field dynamics and entropic gravity.
Resolved the Kobakhidze decoherence objection via Debye-suppressed matter coupling.
Identified the scalar field as testable using neutron gravitational resonance spectroscopy.

Abstract

Paper XXXIII in the VFD series. We show that detection of the scalar folding field σf predicted by Vacuum Folding Dynamics need not rely on parametric amplification (Mathieu instability) but can instead exploit catalyzed stochastic vacuum transitions via Kramers escape and stochastic resonance in a Casimir metamaterial. The paper derives the Kramers escape rate, stochastic resonance enhancement, and identifies the nucleation barrier scaling as the decisive experimental question. A new connection to Verlinde's entropic gravity programme is established, resolving the Kobakhidze decoherence objection through the Debye-suppressed σf–matter coupling, and identifying σf as a quintessence scalar field testable via neutron gravitational resonance spectroscopy.

Stochastic Resonance and Catalyzed Vacuum Transitions: Beyond Parametric Amplification

Key Points

Abstract

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