Approximation of Slow Attracting Manifolds in Chemical Kinetics by Trajectory-Based Optimization Approaches

Reinhardt, Volkmar; Winckler, Miriam; Lebiedz, Dirk

doi:10.1021/jp0739925

Cited by 32 publications

(39 citation statements)

References 38 publications

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“…In this section we consider a small test mechanism, which has already been used for model reduction purposes in [31,36,37]. It consists of six chemical species involved in six elementary reactions constrained by two element mass conservation relations for hydrogen and oxygen: …”

Section: Results: Application To Model Hydrogen Combustion Reaction Mmentioning

confidence: 99%

“…The successive relaxation of chemical forces causes curvature in the reaction trajectories (in the sense of velocity change along the trajectory). Therefore, in [31,32] Φ…”

Section: Optimization Criterionmentioning

confidence: 99%

“…In the original work [21] the entropy production rate (1) has been chosen as a criterion Φ in (2a) and following the fundamental idea to search for an entropy-related extremum principle that characterizes trajectories on or near slow attracting manifolds we discuss geometric criteria in [31]. In Section 4. we show that the latter are superior to the previously used entropy production rate and yield accurate approximations of slow invariant manifolds for an example model of chemical kinetics.…”

Section: Optimization Criterionmentioning

confidence: 99%

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Entropy-Related Extremum Principles for Model Reduction of Dissipative Dynamical Systems

Lebiedz

2010

Entropy

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Chemical kinetic systems are modeled by dissipative ordinary differential equations involving multiple time scales. These lead to a phase flow generating anisotropic volume contraction. Kinetic model reduction methods generally exploit time scale separation into fast and slow modes, which leads to the occurrence of low-dimensional slow invariant manifolds. The aim of this paper is to review and discuss a computational optimization approach for the numerical approximation of slow attracting manifolds based on entropy-related and geometric extremum principles for reaction trajectories.

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Section: Results: Application To Model Hydrogen Combustion Reaction Mmentioning

confidence: 99%

“…The successive relaxation of chemical forces causes curvature in the reaction trajectories (in the sense of velocity change along the trajectory). Therefore, in [31,32] Φ…”

Section: Optimization Criterionmentioning

confidence: 99%

Section: Optimization Criterionmentioning

confidence: 99%

See 1 more Smart Citation

Entropy-Related Extremum Principles for Model Reduction of Dissipative Dynamical Systems

Lebiedz

2010

Entropy

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“…However, for chemical reaction systems, there is no example of deriving the equation that describes a chemical change directly based on entropy production or on a Lyapunov function that does not use a chemical kinetics equation. Gorban et al [18][19][20] and Lebiedz [21][22][23] utilized the second law of thermodynamics to determine the so-called slow invariant manifold (SIM) or the so-called low-dimensional manifold (LDM). Gorban et al [18][19][20] utilized the basis orthonormal with respect to their "entropic" scalar product that uses the Hessian of a Lyapunov function (the free energy of a perfect gas in a constant volume at constant temperature) because their almost orthogonal "projector" that defines SIM helps convergence to determine SIM [20].…”

Section: Introductionmentioning

confidence: 99%

Reaction Kinetics Path Based on Entropy Production Rate and Its Relevance to Low-Dimensional Manifolds

Kojima

2014

Entropy

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Abstract:The equation that approximately traces the trajectory in the concentration phase space of chemical kinetics is derived based on the rate of entropy production. The equation coincides with the true chemical kinetics equation to first order in a variable that characterizes the degree of quasi-equilibrium for each reaction, and the equation approximates the trajectory along at least final part of one-dimensional (1-D) manifold of true chemical kinetics that reaches equilibrium in concentration phase space. Besides the 1-D manifold, each higher dimensional manifold of the trajectories given by the equation is an approximation to that of true chemical kinetics when the contour of the entropy production rate in the concentration phase space is not highly distorted, because the Jacobian and its eigenvectors for the equation are exactly the same as those of true chemical kinetics at equilibrium; however, the path or trajectory itself is not necessarily an approximation to that of true chemical kinetics in manifolds higher than 1-D. The equation is for the path of steepest descent that sufficiently accounts for the constraints inherent in chemical kinetics such as element conservation, whereas the simple steepest-descent-path formulation whose Jacobian is the Hessian of the entropy production rate cannot even approximately reproduce any part of the 1-D manifold of true chemical kinetics except for the special case where the eigenvector of the Hessian is nearly identical to that of the Jacobian of chemical kinetics.

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“…Therefore, much effort has been devoted to setting up automated model reduction procedures based (explicitly or implicitly) on the notion of SIM: The method of invariant grids (MIG) [6,7], the computational singular perturbation (CSP) method [29][30][31], the intrinsic low dimensional manifold (ILDM) [27,28], the invariant constrained equilibrium edge preimage curve method (ICE-PIC) [32], the equation-free approaches [33], the method of minimal entropy production trajectories (MEPT) [35] and minimum curvature [36], the constrained runs algorithm in [34] and the finite-time Lyapunov analysis in [37] are some representative examples.…”

Section: Introductionmentioning

confidence: 99%

The Role of Thermodynamics in Model Reduction When Using Invariant Grids

Chiavazzo¹,

Karlin²,

Gorban

2010

CiCP

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Abstract. In the present work, we develop in detail the process leading to reduction of models in chemical kinetics when using the Method of Invariant Grids (MIG). To this end, reduced models (invariant grids) are obtained by refining initial approximations of slow invariant manifolds, and used for integrating smaller and less stiff systems of equations capable to recover the detailed description with high accuracy. Moreover, we clarify the role played by thermodynamics in model reduction, and carry out a comparison between detailed and reduced solutions for a model hydrogen oxidation reaction.

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Approximation of Slow Attracting Manifolds in Chemical Kinetics by Trajectory-Based Optimization Approaches

Cited by 32 publications

References 38 publications

Entropy-Related Extremum Principles for Model Reduction of Dissipative Dynamical Systems

Entropy-Related Extremum Principles for Model Reduction of Dissipative Dynamical Systems

Reaction Kinetics Path Based on Entropy Production Rate and Its Relevance to Low-Dimensional Manifolds

The Role of Thermodynamics in Model Reduction When Using Invariant Grids

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