Author: Dr. Jayashree Sinha & Dr. Amardeep Sinha & Dr. Koomkoom Khawas
DOI Link: https://doi.org/10.70798/Bijmrd/02110005
Abstract: Mathematics plays an integral role in understanding and quantifying energy changes in chemical reactions. This article delves into mathematical methods, particularly linear algebra, that underpins the analysis of chemical kinetics and energy transformations. It emphasizes the application of stoichiometry, mass conservation laws, and rate equations to evaluate reaction rates and predict feasible reaction pathways. The discussion highlights Bowen’s contributions to mathematically describing chemical reactions, using conservation principles to identify independent reactions in a mixture. Theoretical concepts such as enthalpy, Gibbs free energy, and activation energy are explored, alongside practical applications in thermodynamics, biochemistry, and industrial kinetics. For instance, energy calculations aid in optimizing catalytic processes, analyzing metabolic pathways, and enhancing reaction efficiencies. These mathematical approaches bridge experimental observations with theoretical models, enabling a deeper understanding of chemical processes and their energy dynamics. By incorporating rigorous mathematical frameworks, the study advocates for a broader adoption of these methods in chemical research and engineering. This comprehensive perspective illustrates how integrating mathematics with chemistry not only enhances precision but also opens avenues for innovation in scientific and industrial applications.
Keywords: kinetics, reaction rate, independent reactions, dimensionality reduction, stoichiometry.
Page No: 51-60