Thermodynamics of chemical waves

Avanzini, Francesco; Falasco, Gianmaria; Esposito, Massimiliano

doi:10.1063/1.5126528

Cited by 38 publications

(26 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We have restricted ourselves to the global thermodynamic description of Hopf instability and traveling waves in this report. As all conservation laws of the closed system are broken here by chemostating in the corresponding open system, the semigrand Gibbs free energy is equivalent to the system's energetic entity at the local level [52]. Our previous study [40] found proportionality of total EPR with global concentration profile in Turing-Hopf overlapping regime.…”

Section: Discussionmentioning

confidence: 95%

Nonequilibrium thermodynamics of glycolytic traveling wave: Benjamin-Feir instability

Kumar,

Gangopadhyay

2021

Preprint

View full text Add to dashboard Cite

Evolution of the nonequilibrium thermodynamic entities corresponding to dynamics of the Hopf instabilities and traveling waves at a nonequilibrium steady state of a spatially extended glycolysis model is assessed here by implementing an analytically tractable scheme incorporating complex Ginzberg-Landau equation(CGLE). In the presence of self and cross diffusion, a more general amplitude equation exploiting the multiscale Krylov-Bogoliubov averaging method serves as an essential tool to reveal the various dynamical instability criteria, specially Benjamin-Feir(BF) instability, to estimate the corresponding nonlinear dispersion relation of the traveling wave pattern. The critical control parameter, wavenumber selection criteria, and magnitude of the complex amplitude for traveling waves are modified by self-and cross-diffusion coefficients within the oscillatory regime, and their variabilities are exhibited against the amplitude equation. Unlike the traveling waves, a low amplitude broad region appears for the Hopf instability in the concentration dynamics as the system phase passes through minima during its variation with the control parameter. The total entropy production rate of the uniform Hopf oscillation and glycolysis wave not only qualitatively reflects the global dynamics of concentrations of intermediate species but almost quantitatively. Despite the crucial role of diffusion in generating and shaping the traveling waves, the diffusive part of the entropy production rate has a negligible contribution to the system's total entropy production rate. The Hopf instability shows a more complex and colossal change in the energy profile of the open nonlinear system than so in the traveling waves. A detailed analysis of BF instability shows a contrary nature of the semigrand Gibbs free energy with discrete and continuous wavenumbers for the traveling wave. We hope the Hopf and traveling wave pattern around the BF instability in terms of energetics and dissipation would open up new applications of such dynamical phenomena.

show abstract

Section: Discussionmentioning

confidence: 95%

Nonequilibrium thermodynamics of glycolytic traveling wave: Benjamin-Feir instability

Kumar,

Gangopadhyay

2021

Preprint

View full text Add to dashboard Cite

show abstract

“…e di erent role played by the 𝑌 𝑝 and 𝑌 𝑓 specie provides a rigorous ground to identify the thermodynamic potential of open CRNs and to decompose the entropy production rate (13). As in equilibrium thermodynamics when passing from the canonical to the gran canonical ensemble, the thermodynamic potential G is obtained from the Gibbs free energy 𝐺 by eliminating the energetic contributions of the ma er exchanged with the particle reservoir that in this context corresponds to the chemostats.…”

Section: Wcmentioning

confidence: 99%

“…is theory has been used to quantify the energetic cost for creating pa erns [12] and waves [13], and sustaining the growth process of macromolecules, like copolymers [14][15][16] and biomolecules [17]. Its connections to information geometry [18], as well as to thermodynamic uncertainty relations and speed limits [19], have been recently investigated.…”

Section: Introductionmentioning

confidence: 99%

Thermodynamics of Concentration vs Flux Control in Chemical Reaction Networks

Avanzini,

Esposito

2021

Preprint

Self Cite

View full text Add to dashboard Cite

We investigate the thermodynamic implications of two control mechanisms of open chemical reaction networks. e rst controls the concentrations of the species that are exchanged with the surroundings, while the other controls the exchange uxes. 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 ux control as well.is implies that the thermodynamic potential and the fundamental forces driving chemical reaction networks out of equilibrium can be identi ed 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 ux control may lead to fundamentally di erent regimes where systems achieve stationary growth.

show abstract

“…The application of stochastic thermodynamics to chemical reaction networks is a relatively young [ 34 , 35 , 36 , 37 ], and active field of research [ 38 ]. Recent works covered advances in energy-efficient dissipative chemical synthesis [ 39 ], and provided important extensions from homogeneous mixtures, ideal, and elementary chemical reactions, to spatially extended reaction-diffusion systems [ 40 , 41 ], non-ideal [ 42 ], and non-elementary chemical reaction networks [ 43 ]. Furthermore, thermodynamically consistent coarse-graining rules for chemical reaction networks were derived only recently [ 44 ].…”

Section: Introductionmentioning

confidence: 99%

A Drive towards Thermodynamic Efficiency for Dissipative Structures in Chemical Reaction Networks

Ueltzhöffer

Costa

Cialfi

et al. 2021

Entropy

View full text Add to dashboard Cite

Dissipative accounts of structure formation show that the self-organisation of complex structures is thermodynamically favoured, whenever these structures dissipate free energy that could not be accessed otherwise. These structures therefore open transition channels for the state of the universe to move from a frustrated, metastable state to another metastable state of higher entropy. However, these accounts apply as well to relatively simple, dissipative systems, such as convection cells, hurricanes, candle flames, lightning strikes, or mechanical cracks, as they do to complex biological systems. Conversely, interesting computational properties—that characterize complex biological systems, such as efficient, predictive representations of environmental dynamics—can be linked to the thermodynamic efficiency of underlying physical processes. However, the potential mechanisms that underwrite the selection of dissipative structures with thermodynamically efficient subprocesses is not completely understood. We address these mechanisms by explaining how bifurcation-based, work-harvesting processes—required to sustain complex dissipative structures—might be driven towards thermodynamic efficiency. We first demonstrate a simple mechanism that leads to self-selection of efficient dissipative structures in a stochastic chemical reaction network, when the dissipated driving chemical potential difference is decreased. We then discuss how such a drive can emerge naturally in a hierarchy of self-similar dissipative structures, each feeding on the dissipative structures of a previous level, when moving away from the initial, driving disequilibrium.

show abstract

Thermodynamics of chemical waves

Cited by 38 publications

References 43 publications

Nonequilibrium thermodynamics of glycolytic traveling wave: Benjamin-Feir instability

Nonequilibrium thermodynamics of glycolytic traveling wave: Benjamin-Feir instability

Thermodynamics of Concentration vs Flux Control in Chemical Reaction Networks

A Drive towards Thermodynamic Efficiency for Dissipative Structures in Chemical Reaction Networks

Contact Info

Product

Resources

About