Abstract
This paper formalizes a particle-free, emergent theory of time by extending the Dimensionally Extended Holographic Projection (DEHP) model and Informational Exomemory Cosmology (IEC). While standard general relativity treats time as an immutable fourth coordinate dimension bound within a continuous spacetime continuum, we reinterpret time as a macroscopic, non-fundamental byproduct of quantum information processing constraints. Operating on the foundational axiom that the universe's baseline is a continuous, two-dimensional viscoelastic phase fluid substrate (z=0), we demonstrate that this ground state—the Garden State—is inherently static and timeless. Time sparks into operational existence exclusively in the projected three-dimensional volumetric bulk (z > 0) as a localized rendering delay (propagation latency) encountered when the substrate computes the Von Neumann entanglement entropy load of vertical mass-energy wave crests ("knots"). We provide a fluidic, material derivation of gravitational time dilation, reinterpreting thermodynamic aging as the localized structural strain of resisting a manifold's natural cascading geodesic flow. Finally, we outline explicit engineering vectors to modulate this rendering latency using phase-inverted harmonic fields to achieve localized phase stabilization and material fatigue reversal under the DEHP template.
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This work is licensed under a Creative Commons Attribution 4.0 License.
Recommended Citation
Eckes, Christopher L., "Chronological Latency: The Viscoelastic Rendering Delay of Three-Dimensional Projective Knots under the DEHP Framework", Technical Disclosure Commons, ()
https://www.tdcommons.org/dpubs_series/10907