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Quantum Criticality at the Origin of Life

Why life persists at the edge of chaos is a question at the very heart of evolution. Here we show that molecules taking part in biochemical processes from small molecules to proteins are critical quantum mechanically. Electronic Hamiltonians of biomolecules are tuned exactly to the critical point of the metal-insulator transition separating the Anderson localized insulator phase from the conducting disordered metal phase. Using tools from Random Matrix Theory we confirm that the energy level statistics of these biomolecules show the universal transitional distribution of the metal-insulator critical point and the wave functions are multifractals in accordance with the theory of Anderson transitions. The findings point to the existence of a universal mechanism of charge transport in living matter. The revealed bio-conductor material is neither a metal nor an insulator but a new quantum critical material which can exist only in highly evolved systems and has unique material properties.

preprint2015arXivOpen access
Gabor VattayDennis SalahubIstvan CsabaiAli NassimiStuart A. Kaufmann
Biological Physicsphysics.chem-phPopulations and Evolutioncond-mat.dis-nnquant-ph
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Gabor VattayDennis SalahubIstvan CsabaiAli NassimiStuart A. Kaufmann

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