Litcius/Paper detail

Dissipation-driven selection of states in non-equilibrium chemical networks

Daniel Maria Busiello, Shiling Liang, Francesco Piazza, Paolo De Los Rios

2021Communications Chemistry40 citationsDOIOpen Access PDF

Abstract

Life has most likely originated as a consequence of processes taking place in non-equilibrium conditions (e.g. in the proximity of deep-sea thermal vents) selecting states of matter that would have been otherwise unfavorable at equilibrium. Here we present a simple chemical network in which the selection of states is driven by the thermodynamic necessity of dissipating heat as rapidly as possible in the presence of a thermal gradient: states participating to faster reactions contribute the most to the dissipation rate, and are the most populated ones in non-equilibrium steady-state conditions. Building upon these results, we show that, as the complexity of the chemical network increases, the velocity of the reaction path leading to a given state determines its selection, giving rise to non-trivial localization phenomena in state space. A byproduct of our studies is that, in the presence of a temperature gradient, thermophoresis-like behavior inevitably appears depending on the transport properties of each individual state, thus hinting at a possible microscopic explanation of this intriguing yet still not fully understood phenomenon.

Topics & Concepts

DissipationThermodynamic equilibriumSelection (genetic algorithm)Statistical physicsThermophoresisThermalTemperature gradientThermal management of electronic devices and systemsState (computer science)Thermal equilibriumChemical equilibriumPhysicsThermodynamicsComputer scienceMeteorologyNanofluidMechanical engineeringArtificial intelligenceEngineeringAlgorithmAdvanced Thermodynamics and Statistical Mechanicsthermodynamics and calorimetric analysesField-Flow Fractionation Techniques