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Thermodynamics of Concentration vs Flux Control in Chemical Reaction Networks
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In this paper, the thermodynamic implications of two control mechanisms of open chemical reaction networks were investigated, i.e., the first controls the concentrations of the species that are exchanged with the surroundings, while the other controls the exchange fluxes.Abstract:
We investigate the thermodynamic implications of two control mechanisms of open chemical reaction networks. The first controls the concentrations of the species that are exchanged with the surroundings, while the other controls the exchange fluxes. We show that the two mechanisms can be mapped one into the other and that the thermodynamic theories usually developed in the framework of concentration control can be applied to flux control as well. This implies that the thermodynamic potential and the fundamental forces driving chemical reaction networks out of equilibrium can be identified in the same way for both mechanisms. By analyzing the dynamics and thermodynamics of a simple enzymatic model we also show that, while the two mechanisms are equivalent a steady state, the flux control may lead to fundamentally different regimes where systems achieve stationary growth.read more
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Length and sequence relaxation of copolymers under recombination reactions.
Alex Blokhuis,David Lacoste +1 more
TL;DR: In this paper, the authors describe the kinetics and thermodynamics of copolymers undergoing recombination reactions, which are important for prebiotic chemistry, and compare the predictions of both approaches for the relaxation of thermodynamic quantities towards equilibrium.