Sudarshana Laha scite author profile

The kinetics of chemical reactions are determined by the law of mass action, which has been successfully applied to homogeneous, dilute mixtures. At nondilute conditions, interactions among the components can give rise to coexisting phases, which can significantly alter the kinetics of chemical reactions. Here, we derive a theory for chemical reactions in coexisting phases at phase equilibrium. We show that phase equilibrium couples the rates of chemical reactions of components with their diffusive exchanges between the phases. Strikingly, the chemical relaxation kinetics can be represented as a flow along the phase equilibrium line in the phase diagram. A key finding of our theory is that differences in reaction rates between coexisting phases stem solely from phase-dependent reaction rate coefficients. Our theory is key to interpreting how concentration levels of reactive components in condensed phases control chemical reaction rates in synthetic and biological systems.

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Parasitic behavior in competing chemically fueled reaction cycles

Schwarz

Laha

Janssen

et al. 2021

Chem. Sci.

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Parasitic Behavior in Competing Chemically Fueled Reaction Cycles

Schwarz¹,

Laha²,

Janssen³

et al. 2021

Preprint

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Non-equilibrium reaction cycles serve as model systems of the intricate reaction networks of life. Rich and dynamic behavior is observed when such reaction cycles regulate assembly processes, such as phase separation. However, it remains unclear how the interplay between multiple reaction cycles affects the success of such assemblies. To tackle this question, we created a library of molecules that compete for a common fuel that transiently activates products. Often, the competition for fuel implies that a competitor decreases the lifetime of these products. However, in cases where the transient competitor product can phase separate, such a competitor can increase the survival time of one product. Moreover, in the presence of oscillatory fueling, the same mechanism reduces variations in the product concentration while the concentration variations of the competitor product are enhanced. Like a parasite, the product benefits from the protection of the host against deactivation and increases its robustness against fuel variations at the expense of the robustness of the host. Such a parasitic behavior in multiple fuel-driven reaction cycles represents a lifelike trait, paving the way for the bottom-up design of synthetic life.

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Sudarshana Laha

Chemical Kinetics and Mass Action in Coexisting Phases

Parasitic behavior in competing chemically fueled reaction cycles

Parasitic Behavior in Competing Chemically Fueled Reaction Cycles

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