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.

More John Surmont's questions See All
Similar questions and discussions