Chemical-Reaction-Controlled Phase Separated Drops: Formation, Size Selection, and Coarsening

Chemical-Reaction-Controlled Phase Separated Drops: Formation, Size Selection, and Coarsening

Phase separation under nonequilibrium conditions is exploited by biological cells to organize their cytoplasm but remains poorly understood as a physical phenomenon. Here, we study a ternary fluid model in which phase-separating molecules can be converted into soluble molecules, and vice versa, via...

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Veröffentlicht in:Physical review letters 2018-02, Vol.120 (7), p.078102-078102, Article 078102
Hauptverfasser: Wurtz, Jean David, Lee, Chiu Fan
Format: Artikel
Sprache:eng
Schlagworte:
Chemical reactions
Coarsening
Computer simulation
Cytoplasm
Drop size
Nonequilibrium conditions
Organic chemistry
Ostwald ripening
Phase separation
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Zusammenfassung:Phase separation under nonequilibrium conditions is exploited by biological cells to organize their cytoplasm but remains poorly understood as a physical phenomenon. Here, we study a ternary fluid model in which phase-separating molecules can be converted into soluble molecules, and vice versa, via chemical reactions. We elucidate using analytical and simulation methods how drop size, formation, and coarsening can be controlled by the chemical reaction rates, and categorize the qualitative behavior of the system into distinct regimes. Ostwald ripening arrest occurs above critical reaction rates, demonstrating that this transition belongs entirely to the nonequilibrium regime. Our model is a minimal representation of the cell cytoplasm.
ISSN:0031-9007
1079-7114
DOI:10.1103/physrevlett.120.078102