Cooling down and waking up: feedback cooling switches an unconscious neural computer into a conscious quantum computer

TL;DR

This paper proposes a theory that feedback cooling in the brain enables quantum phenomena like Bose-Einstein condensation, which in turn switches the neural computer from unconscious to conscious states, explaining consciousness emergence.

Contribution

It introduces a novel model linking feedback cooling to quantum coherence in brain microstructures, providing a testable explanation for consciousness.

Findings

Feedback cooling can induce Bose-Einstein condensation in neuronal arrays.

Consciousness correlates with activation of quantum accelerators in the brain.

The model predicts detectable brain cooling during conscious states.

Abstract

This paper sets out a theory of how feedback cooling in the brain switches on consciousness. It explains how cooling reduces thermal noise to the point where macroscale quantum phenomena - crucially Bose-Einstein condensation and long-range coherence - can operate at body temperature. It takes the core idea from Stapp that mind and brain interact via some sort of oscillator and then focuses on a likely candidate: neuronal arrays identified by Stapp as cortical minicolumns. Feedback cooling allows amplifiers to act as refrigerators, and when applied to minicolumns it is suggested that the units perform like quantum accelerators, solid-state devices devised to supercharge standard computers. When the accelerator is idle, as in sleep, we have a neural computer operating unconsciously, but when feedback cooling is activated by thalamocortical loops, it produces a Bose-Einstein condensate, quantum computation, and consciousness. The model explains how macroscale quantum phenomena can operate in a warm and noisy brain, how and why consciousness evolved, and gives insight into puzzling unconscious states like sleepwalking. The model is testable, predicting that cold states in the brain are detectable by magnetic resonance thermometry.