https://wiki.fusiongirl.app:443/index.php?action=history&feed=atom&title=Coherent_Quantum_Effects_in_BiologyCoherent Quantum Effects in Biology - Revision history2026-05-12T09:46:56ZRevision history for this page on the wikiMediaWiki 1.41.0https://wiki.fusiongirl.app:443/index.php?title=Coherent_Quantum_Effects_in_Biology&diff=6993&oldid=prevJonoThora: Psionics expansion (01a + 01b): content authored / LaTeX-restored per local submodule; lint-clean.2026-05-11T20:47:34Z<p>Psionics expansion (01a + 01b): content authored / LaTeX-restored per local submodule; lint-clean.</p>
<p><b>New page</b></p><div>= Coherent Quantum Effects in Biology =<br />
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{{Audience_Sidebar<br />
| difficulty = Advanced<br />
| reading_time = 9 minutes<br />
| prerequisites = Quantum mechanics (coherence, decoherence); basic biochemistry.<br />
| if_too_advanced_see = [[Could_the_Brain_Use_Quantum_Mechanics]]<br />
| if_you_want_the_math_see = [[Celardo_Microtubule_Superradiance]]<br />
}}<br />
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{{Notation<br />
| signature = Mostly-plus.<br />
| units = SI for biological observables; ℏ = c = 1 in field-theoretic expressions.<br />
}}<br />
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'''Coherent quantum effects in biology''' — the field commonly called '''quantum biology''' — is the study of biological processes in which quantum-mechanical coherence, entanglement, or tunnelling play functionally-relevant roles. As of the mid-2020s, quantum biology has progressed from speculative possibility to '''empirically-grounded research programme''' with several well-characterised systems.<br />
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This page summarises the state of the field for context to the framework's claims about [[Biological_Substrate_of_Psi|biological ψ-coupling]].<br />
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== Why it was assumed impossible ==<br />
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The standard objection (formalised by [[Tegmark_Critique_and_Hagan_Rebuttal|Tegmark 2000]] for the consciousness case but applied widely):<br />
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* Biological systems are '''warm''' (T ≈ 310 K) — k<sub>B</sub>T ≈ 0.025 eV thermal noise.<br />
* Biological systems are '''wet''' — surrounded by polar solvents that strongly couple to quantum states.<br />
* Biological systems are '''crowded''' — densely-packed with diverse molecules whose interactions cause decoherence.<br />
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A naïve estimate gives biological decoherence times of 10<sup>−13</sup>–10<sup>−20</sup> s — orders of magnitude shorter than any functionally-relevant biological timescale. The default expectation was that biology is essentially classical at functional scales.<br />
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== Why it turns out to be possible ==<br />
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Three classes of phenomena have demonstrated that biology can sustain quantum coherence on functionally-relevant timescales:<br />
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=== 1. Photosynthetic energy transfer ===<br />
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The defining demonstration. Engel et al. (''Nature'' 2007) used 2D electronic spectroscopy on the Fenna-Matthews-Olson (FMO) complex of green sulfur bacteria to show that:<br />
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* '''Excitonic coherence persists''' for ~ 500 fs at room temperature.<br />
* '''Energy transfer from antenna to reaction centre is near-100% efficient''' — orders of magnitude higher than incoherent random-walk would predict.<br />
* '''The high efficiency is enabled by the coherence''': quantum-superposition states explore multiple transfer paths simultaneously, selecting the optimal route.<br />
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Subsequent work (Collini et al. 2010 in marine cryptophyte algae at room temperature; many groups extending to the LH1-LH2 complex of purple bacteria, Photosystem II of plants) confirmed quantum-coherent energy transfer as a '''general feature''' of photosynthesis.<br />
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This decisively refuted the strong form of the warm-wet-crowded argument: '''biology does use quantum coherence''' at room temperature on functionally-relevant timescales.<br />
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=== 2. Avian magnetoreception ===<br />
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European robins, and likely most migratory birds, navigate using '''quantum-coherent radical-pair''' chemistry in their retinal '''cryptochrome''' protein. Mechanism:<br />
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* A blue-light photon excites a cryptochrome flavin chromophore.<br />
* The excited state transfers an electron to create a short-lived radical pair.<br />
* The radical pair's electron-spin state — singlet vs triplet — depends sensitively on the local magnetic field.<br />
* '''Coherent spin dynamics''' between singlet and triplet states make the chemistry magnetic-field-dependent at the level of ~ 1 μT (Earth's field strength).<br />
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The radical-pair quantum coherence lasts ~ μs — sufficient for the magnetic-field sensitivity to manifest. Experiments with weak radio-frequency fields tuned to the radical-pair coherence frequency disrupt avian magnetoreception — direct in-vivo evidence of quantum-coherent biology.<br />
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=== 3. Enzymatic tunnelling ===<br />
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Many enzymatic reactions involve '''quantum tunnelling''' of hydrogen, electron, or proton through energy barriers that classical kinetics could not surmount at biological temperatures. Kinetic isotope-effect signatures distinguish quantum-tunnelling from classical-thermal mechanisms. Verified in:<br />
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* Alcohol dehydrogenase (Klinman group, 1989+).<br />
* Soybean lipoxygenase (Klinman group, 1996+).<br />
* Many other H/D-transfer reactions.<br />
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These are not '''coherence''' in the same sense as photosynthesis or magnetoreception — tunnelling is a single-particle quantum effect — but they establish that '''quantum mechanics is required''' to describe biochemistry quantitatively.<br />
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=== 4. Olfaction (proposed) ===<br />
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Luca Turin's '''vibration-theory of olfaction''' proposes that smell perception involves '''inelastic electron tunnelling''' through odorant molecules, with tunnelling probability dependent on the odorant's vibrational frequency. Experimental tests are mixed; the proposal remains contested but is taken seriously.<br />
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=== 5. Microtubule electronic states (proposed) ===<br />
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The most contested case in mainstream quantum biology, and the central case for consciousness research. See [[Microtubule]], [[Orchestrated_Objective_Reduction]], [[Bandyopadhyay_Microtubule_Conductance]], [[Celardo_Microtubule_Superradiance]], [[Kalra_Anaesthetic_Microtubule]].<br />
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== Why coherence survives in biology ==<br />
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The general principle: biological '''structure matters'''. The Tegmark calculation assumes a generic warm-wet environment; the actual environment for the relevant coherent state is often:<br />
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* '''Ordered''' (protein scaffolds, lipid arrays, lattice structures).<br />
* '''Shielded''' (hydrophobic protein cores, ordered water).<br />
* '''Symmetric''' — supporting '''subradiant''' or '''decoherence-free subspace''' collective states.<br />
* '''Time-engineered''' — biology has evolved to ensure the coherent state lives just long enough to do its functional work.<br />
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The cumulative effect is that biological coherence times can be much longer than naïve thermal-bath estimates — often by 5–7 orders of magnitude.<br />
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== Generalising to consciousness ==<br />
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The success of quantum biology in photosynthesis, magnetoreception, and enzymology has reopened the question of '''quantum mechanics in cognition'''. The framework's position:<br />
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* The principled "no quantum biology" argument is dead. Biology DOES use quantum coherence at room temperature.<br />
* Specific biological substrates relevant to consciousness ([[Microtubule|microtubules]], [[Biophotons|biophoton-emitting cells]]) show signatures consistent with quantum-coherent processes.<br />
* The αψ F<sub>μν</sub> F<sup>μν</sup> vertex provides a mechanism by which coherent neural EM and biophoton activity couples to the [[Psi_Field|ψ field]] — extending quantum biology beyond the local cellular context.<br />
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This does NOT mean the brain is a "quantum computer" in the technical sense. It means the same kinds of mechanisms that enable photosynthesis efficiency and avian magnetoreception are plausibly operative — to some degree — in neural function.<br />
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== Sanity checks ==<br />
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* '''Photosynthesis without quantum coherence''' would have ~ 50% efficiency (random walk). Observed: ~ 100% efficiency. Discrepancy resolved by quantum coherence. ✓<br />
* '''Avian magnetoreception without radical pairs''' would not show RF-disruption at the predicted frequency. Disruption observed. ✓<br />
* '''Enzymatic tunnelling without quantum mechanics''' would not show kinetic isotope effects of the magnitude observed. Effects observed. ✓<br />
* '''ψ → 0''' (in framework) → all known quantum-biology effects remain; only the framework-specific ψ-coupling channel vanishes. ✓ ([[Sanity_Check_Limits]] §12.)<br />
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== See Also ==<br />
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* [[Could_the_Brain_Use_Quantum_Mechanics]]<br />
* [[Microtubule]]<br />
* [[Biophotons]]<br />
* [[Celardo_Microtubule_Superradiance]]<br />
* [[Tegmark_Critique_and_Hagan_Rebuttal]]<br />
* [[Biological_Substrate_of_Psi]]<br />
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== References ==<br />
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* Engel, G. S., et al. (2007). "Evidence for wavelike energy transfer through quantum coherence in photosynthetic systems." ''Nature'' 446: 782–786.<br />
* Collini, E., Wong, C. Y., Wilk, K. E., Curmi, P. M. G., Brumer, P., Scholes, G. D. (2010). "Coherently wired light-harvesting in photosynthetic marine algae at ambient temperature." ''Nature'' 463: 644–647.<br />
* Ritz, T., Adem, S., Schulten, K. (2000). "A model for photoreceptor-based magnetoreception in birds." ''Biophysical Journal'' 78: 707–718.<br />
* Hore, P. J., Mouritsen, H. (2016). "The radical-pair mechanism of magnetoreception." ''Annual Review of Biophysics'' 45: 299–344.<br />
* Klinman, J. P., Kohen, A. (2013). "Hydrogen tunneling links protein dynamics to enzyme catalysis." ''Annual Review of Biochemistry'' 82: 471–496.<br />
* Lambert, N., et al. (2013). "Quantum biology." ''Nature Physics'' 9: 10–18.<br />
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[[Category:Psionics]]<br />
[[Category:Biology]]<br />
[[Category:Quantum]]</div>JonoThora