This work develops a thermalisation and energy-realisation modulefor Quantum-Informational Metric Genesis Cosmology (QIMG Cosmology). In the combined CBHIRT--QIMG framework, CBHIRT supplies the pre-FRW informational initial conditionsthrough Page-time black-hole correlations, while QIMG describeshow this inherited quantum-informational structure becomesrepresented after FRW activation as effective metric geometryand an informational stress-energy representation. The present paper addresses the next step in this sequence: how the effective informational stress-energy tensor\ (T^info_\) may become physically realised asradiation, matter, temperature, entropy, and hot primordial plasma. The model does not treat raw information as directly orautomatically converting into physical energy. Instead, it proposesa controlled energy-realisation process in which the alreadyestablished QIMG effective geometry and stress-energy representationenter a thermalisation regime and become expressed as physicallyrealised energetic components. The central chain studied in this work is&CBHIRT information (x^) _[I \\&^info_I \\&^rad_+T^matter_+T^plasma_. aligned\]This sequence is interpreted as an informational-geometry-to-physical-energyrealisation process, rather than as a direct information-to-energyconversion. The framework introduces an effective energy-realisation principle, a thermalisation map from \ (T^info_\) to radiation, matter, and plasma stress-energy components, and a conservation conditiondesigned to preserve covariant consistency and Bianchi compatibility. It also discusses radiation genesis, entropy production, baryonic-sectoractivation, connection to the standard Hot Big Bang timeline, CMBinitial conditions, and possible observational consequences. Thus, this work does not replace CBHIRT or QIMG. Rather, it extendsthem by adding the next physical layer. CBHIRT defines the informationalorigin, QIMG defines the post-FRW geometric and stress-energyrepresentation, and the present module investigates how thatrepresentation may become physically realised as the energetic, thermalised early universe.
Darius Seza (Tue,) studied this question.