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Bibliographic Details
Main Author: Diamond, Steven
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.18523
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author Diamond, Steven
author_facet Diamond, Steven
contents Chemical reaction networks in living cells maintain precise control over thousands of metabolites despite operating far from equilibrium under constant perturbations. While mass action kinetics accurately describe the underlying dynamics, the resulting nonlinear differential equations are difficult to analyze and control, particularly for large networks. We propose a simplified model where reaction quotients (the ratios that measure how far reactions are from equilibrium) evolve exponentially toward their equilibrium values when viewed on a logarithmic scale. This principle leads to linear dynamics in log-space, providing several key advantages: analytical solutions exist for arbitrary network topologies, thermodynamic constraints are automatically satisfied through the relationship between reaction quotients and Gibbs free energy, conservation laws decouple from reaction quotient dynamics simplifying both analysis and control design, and external energy sources couple linearly to the dynamics, unifying diverse biological regulatory mechanisms.
format Preprint
id arxiv_https___arxiv_org_abs_2508_18523
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Log-Linear Reaction Quotient Dynamics
Diamond, Steven
Optimization and Control
Chemical reaction networks in living cells maintain precise control over thousands of metabolites despite operating far from equilibrium under constant perturbations. While mass action kinetics accurately describe the underlying dynamics, the resulting nonlinear differential equations are difficult to analyze and control, particularly for large networks. We propose a simplified model where reaction quotients (the ratios that measure how far reactions are from equilibrium) evolve exponentially toward their equilibrium values when viewed on a logarithmic scale. This principle leads to linear dynamics in log-space, providing several key advantages: analytical solutions exist for arbitrary network topologies, thermodynamic constraints are automatically satisfied through the relationship between reaction quotients and Gibbs free energy, conservation laws decouple from reaction quotient dynamics simplifying both analysis and control design, and external energy sources couple linearly to the dynamics, unifying diverse biological regulatory mechanisms.
title Log-Linear Reaction Quotient Dynamics
topic Optimization and Control
url https://arxiv.org/abs/2508.18523