I’m exploring whether negentropic entanglement, conceived as the anti-entropic process through which informational order arises from quantum-thermal or functional fluctuations, has been experimentally investigated in relation to cognitive binding.

In recent theoretical work (e.g., Poznanski, Chauvet, Brändas), negentropic entanglement is proposed as a mechanism for spontaneous ordering within the brain’s functional architecture. It is associated with:

• Reduction of uncertainty through the restructuring of informational redundancy
• The emergence of experienceable forms (e.g., intentionality, self-referential dynamics)
• Cross-scale coherence in functional systems, rather than classical representational encoding

From the ODTBT perspective, this process is modeled as a sine-cosine transductive coupling, where functional unity (i.e., cognitive binding) emerges at the TWIST, an oscillatory threshold that bridges emergent and discrete quantum fluctuations and continuous field coherence.

My question: Has any group empirically explored negentropic ordering or entanglement-like coordination as a precursor to neural or cognitive binding phenomena?

Specifically:

• Have EEG, MEG, or fMRI studies been used to correlate low-entropy or phase-synchronized states with perceptual or semantic integration?
• Are there thermodynamic, metabolic, or biophysical signatures (e.g., entropy flux, temperature gradients) linked to coherent cognitive states?
• Have quantum-biological or field-based models attempted lab-scale validation of these principles?

Any relevant research, methodologies, or hypotheses, especially those addressing binding without representational overlap, would be greatly appreciated.