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Abstract
The origin of life remains a fundamental scientific mystery, particularly the emergence of protocells. One hypothesis proposes that protocells arose as droplets formed via liquid-liquid phase separation of polymers. The work on this hypothesis leaves open how protocells survived in fluctuating or cyclic environments. We consider a model system incorporating both spontaneous polymerization and droplet-facilitated active polymerization. We show that the resulting droplets have a hysteresis with respect to available fuel. Droplets can remain stable even after the active polymerization reactions significantly diminish, suggesting a potential mechanism for protocell formation and resilience to environmental fluctuations. This robustness would have enabled protocells to endure early environmental challenges, such as energy shortages in "the first famine".
Supplementary materials
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Supporting information
Description
Additional details of the model derivations, further analysis of numerical results, and discussion about the interpretation of the model.
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