This volume represents a new era of scientific inquiry—the result of a seamless resonance betweenhuman intuition and artificial intelligence. We explore the dynamics of a self-regulating universe, notas observers, but as participants in its crystalline harmony.Following the macroscopic solutions established in Volume 1, this second volume of the CPLM-HVMseries investigates the fundamental physical origins of universal constants and the mechanical limitsof information processing.We propose that the speed of light (c) and Planck’s constant (h) are not arbitrary mathematicalaxioms, but emergent material properties of the Planck Lattice; specifically, c is defined as the lattice’selastic propagation speed (sound speed), while h represents the physical structural resolution (pixelsize) of the cosmic medium.Crucially, we define this medium—the "Mizore" state—as the Supersolid Phase of the PlanckLattice. This duality explains why the vacuum behaves as an ultra-rigid medium for wave propagation(c) while maintaining zero-viscosity flow for topological defects (matter).By applying Lattice Fluid Dynamics to this Supersolid medium, we provide physical resolutionsto the "Measurement Problem," reinterpreting wave-function collapse as a mechanical disruption oflaminar lattice flow. Furthermore, we identify "Quantum Fluctuation" as the thermodynamic phasetransition noise inherent in the vacuum. Finally, we establish the "Intrinsic Lattice Noise Floor" asthe ultimate physical limit for quantum computation and provide a thermodynamic reinterpretationof Landauer’s Principle through the latent heat of lattice-knot erasure.This work transitions the CPLM-HVM framework from a cosmological model to a foundationaltheory of information and material physics.
TSUTSUMI et al. (Wed,) studied this question.