Research Article
Advancements in Thermodynamic Modeling: Bridging Classical Theory and Computational Techniques
Diriba Gonfa Tolasa*
Issue:
Volume 13, Issue 1, June 2025
Pages:
1-9
Received:
30 December 2024
Accepted:
13 January 2025
Published:
21 March 2025
DOI:
10.11648/j.ejb.20251301.11
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Abstract: Thermodynamics, a cornerstone of physics, focuses on the interplay between heat, work, temperature, and the statistical behavior of system s. In recent decades, the field has witnessed significant advancements in modeling techniques, integrating classical theories with modern computational methods. This paper reviews the evolution of thermodynamic modeling, highlighting both the limitations of traditional approaches and the emergence of innovative computational strategies such as molecular dynamics, Monte Carlo simulations, and machine learning. Classical thermodynamics, grounded in macroscopic observations, has established fundamental principles that govern energy and matter. However, traditional models often fall short in accurately predicting the behavior of complex systems, especially at the molecular or atomic level. Computational techniques have surfaced as powerful tools, enabling researchers to simulate intricate systems that were previously intractable, thereby enhancing our understanding of thermodynamic phenomena. The integration of classical and computational approaches has led to the development of hybrid models that leverage the strengths of both domains. These hybrid frameworks facilitate the exploration of complex phenomena, allowing for a more comprehensive understanding of thermodynamic systems and their applications in materials science, energy systems, and biological processes. Furthermore, the advent of machine learning technologies has provided new avenues for optimization and predictive modeling, significantly improving the performance of energy conversion systems. Despite these advancements, challenges remain. Issues such as data quality, system complexity, and interpret ability of machine learning models necessitate ongoing research. This paper employs a comprehensive literature review methodology to synthesize findings from various sources, identifying key themes and trends in thermodynamic modeling. It emphasizes the importance of interdisciplinary approaches that combine thermodynamics with fields like materials science and engineering. Ultimately, this study underscores the significance of bridging classical thermodynamic principles with computational techniques. It posits that continued research in this area will not only deepen our understanding of thermodynamic systems but also pave the way for innovations that address pressing global challenges, including energy efficiency and sustainability. Through this integration, the potential for breakthroughs in understanding the fundamental principles governing energy and matter is immense, setting the stage for future advancements in the field.
Abstract: Thermodynamics, a cornerstone of physics, focuses on the interplay between heat, work, temperature, and the statistical behavior of system s. In recent decades, the field has witnessed significant advancements in modeling techniques, integrating classical theories with modern computational methods. This paper reviews the evolution of thermodynamic ...
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