CMG_VI_Microscopic_Origin_of_Inertia_and_Dark_Energy_in_Controlled_Mean-Field_Baseline_with_Reduced-DPN_Fluctuation_Validation

Causal Memory Gravity VI and its supplementary addendum study the microscopic origin of inertia, dark-energy-like behavior, and thermal criticality within the Dynamic Planck Network framework. The main paper develops a controlled mean-field baseline in which collective DPN response is connected to effective inertia and late-time vacuum-like dynamics, while reduced-DPN fluctuation tests are used to check the stability of the approximation. The supplementary addendum extends this analysis by examining thermal criticality, DPN spectral matching, and renormalization-group closure as consistency conditions for the microscopic construction. Together, the documents clarify how macroscopic inertial and cosmological sectors may emerge from network-level critical behavior, while separating derived structure from quantities that still require full dynamical calibration. They serve as the CMG VI foundation for connecting DPN statistical dynamics, mean-field validation, and the effective origin of inertia and dark energy.

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