Litcius/Paper detail

The thermodynamic efficiency of the Lorenz system

Álvaro G. López, Fernando Benito, Juan Sabuco, Alfonso Delgado-Bonal

2023Chaos Solitons & Fractals17 citationsDOIOpen Access PDF

Abstract

We study the thermodynamic efficiency of the Malkus–Lorenz waterwheel. For this purpose, we derive an exact analytical formula that describes the efficiency of this dissipative structure as a function of the phase space variables and the constant parameters of the dynamical system. We show that, generally, as the machine is progressively driven far from thermodynamic equilibrium by increasing its uptake of matter from the environment, it also tends to increase its efficiency. However, sudden drops in the efficiency are found at critical bifurcation points leading to chaotic dynamics. We relate these discontinuous crises in the efficiency to a reduction of the attractor’s average value projected along the phase space dimensions that contribute to the rate of entropy generation in the system. In this manner, we provide a thermodynamic criterion that, presumably, governs the evolution of far-from-equilibrium dissipative systems towards their self-assembly and synchronization into increasingly complex networks and structures.

Topics & Concepts

Dissipative systemPhase spaceAttractorStatistical physicsLorenz systemChaoticSecond law of thermodynamicsThermodynamic equilibriumCatastrophe theoryThermodynamicsBifurcationComplex systemParameter spaceEntropy (arrow of time)PhysicsMathematicsNonlinear systemComputer scienceMathematical analysisQuantum mechanicsEngineeringGeotechnical engineeringStatisticsArtificial intelligenceAdvanced Thermodynamics and Statistical MechanicsNonlinear Dynamics and Pattern Formationstochastic dynamics and bifurcation