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Abstract
Homochirality represents a hallmark of life, and its emergence on the pre-biotic Earth remains elusive. Here we demonstrate a spontaneous pathway to homochirality, where a conglomerate-forming chiral species evolves from an initial perfectly symmetric state, i.e., a racemic solution, to a fully homochiral state, where only enantiopure crystals of one handedness are present in the suspension. It entails first the establishment of supersaturated conditions, e.g., because of either solvent evaporation or cooling, then stochastic nucleation of enantiopure crystals as the symmetry breaking event, and finally asymmetry amplification and complete deracemization via temperature fluctuations. After developing a stochastic modeling platform and an experimental setup, we confirm the plausibility of this pathway through both detailed simulations and laboratory experiments. We also show how from a variety of local homochiral states of different handedness, a global homochiral state may emerge via merging and deracemizing. Because the external conditions triggering supersaturation creation, nucleation, and deracemization via temperature cycling must have existed also on the pre-biotic Earth, the proposed spontaneous pathway may indeed have played a role in the emergence of life on Earth.
