Localized Quantum Biocosmic Consciousness (LQBC) Version 3 : A Physically Constrained, Multiscale Framework with Geophysical Evidence and Testable Predictions

The problem of consciousness—how subjective experience arises from physical processes—remains one of the most unresolved challenges in contemporary science. Existing models, including Integrated Information Theory (IIT), Global Workspace Theory (GWT), and quantum proposals such as Orch‑OR, offer partial insights but do not integrate biological, physical, and geophysical dimensions within a unified explanatory framework. This paper introduces the Localized Quantum Biocosmic Consciousness (LQBC) model, a theoretical framework proposing that conscious states may arise from a multi‑scale coherence structure coupling quantum‑biological substrate, neural field dynamics, and geomagnetic–cosmic fluctuations. The model is formalized through two core mathematical constructs: Ψᶜ, a quantum‑biological coupling function encoding coherence lifetimes and dipole synchrony within microtubular lattices. W₍c₎, a field‑synchronization operator modeling phase‑locking across neuronal oscillators under weak environmental field modulation. LQBC links subcellular quantum coherence (τcoh), neural oscillatory regimes (EEG/MEG), and planetary electromagnetic rhythms (e. g. , Schumann resonances) through a hybrid Hamiltonian. Empirical evaluation is outlined through cross‑scale experimental protocols involving MEG/EEG–geomagnetic correlation, THz spectroscopy of microtubules, anesthetic perturbation studies, and hybrid quantum‑classical simulations. By offering falsifiable predictions and measurable coupling metrics, the LQBC framework provides a scientifically testable basis for investigating quantum‑biophysical contributions to consciousness and may lay the foundation for a future empirical discipline of quantum biocosmic neuroscience.