Asian Journal of Physical and Chemical Sciences

Thermodynamic parameters play a fundamental role in characterizing the feasibility, spontaneity, and equilibrium of both physical and chemical processes. Key quantities—including enthalpy (ΔH), which measures heat exchange; entropy (ΔS), which quantifies disorder; Gibbs free energy (ΔG), which determines spontaneity; and the equilibrium constant (K), which describes the position of equilibrium—provide a quantitative framework for analyzing energy transformations. Understanding the interrelationships among these parameters enables scientists and engineers to predict the direction of reactions, optimize conditions, and design efficient systems. This paper presents a comprehensive overview of these thermodynamic concepts, emphasizing their theoretical foundations, mathematical relationships, and practical applications across diverse areas such as chemical reactions, materials science, and energy engineering. By integrating these insights, the study offers a structured approach to interpreting thermodynamic behavior in both research and industrial contexts.