What question did this study set out to answer?

The aim is to clarify the Kinematic-Functionalist foundations of the Resonant Lattice Model and its implications for cosmology.

March 4, 2026Open Access

Addendum of Clarification: Kinematic-Functionalism in the Resonant Lattice Model: Distinguishing Emergent Topology from Rigid Substrates

Key Points

The aim is to clarify the Kinematic-Functionalist foundations of the Resonant Lattice Model and its implications for cosmology.
Mathematically decoupled vacuum fluid from localized topological geometry.
Analyzed 'Event Horizons' as topological yield boundaries rather than singularities.
Aligned kinematic drag with diffusion damped oscillations.
Established that the RLM lattice functions as a dynamic interference map.
Resolved misinterpretations that equate the model with rigid substrates.
Demonstrated absence of thermodynamic friction in the modeled interactions.

Abstract

The Resonant Lattice Model (RLM) resolves late-stage cosmological tensions by introducing a10−4 Mpc−1 macroscopic impedance—a geometric drag acting upon a continuous superfluidvacuum. However, utilizing terminology such as "lattice" and "impedance" risks misinterpretation as a return to a rigid, dissipative aether. This clarification paper establishes the strict Kinematic-Functionalist parameters of the RLM. We mathematically decouple the vacuum fluid (a non-interacting Substrate Constant) from the localized topological geometry (dynamic Algorithmic Variables). By demonstrating that Event Horizons act as topological yield boundaries rather than singularities, and by aligning kinematic drag with observed diffusion damped oscillations, we establish that the RLM lattice is a dynamic interference map devoid of thermodynamic friction

Addendum of Clarification: Kinematic-Functionalism in the Resonant Lattice Model: Distinguishing Emergent Topology from Rigid Substrates

Key Points

Abstract

Cite This Study