A Componential Reduction to the Euler-Lagrange Equation Using Energy Structure Theory

Authors

  • Saeed Shahsavari Department of Mechanical Engineering, Isfahan University of Technology, Isfahan, Iran.
  • Pooya Torkaman School of Metallurgy and Material Engineering, Iran University of Science and Technology, Tehran, Iran

DOI:

https://doi.org/10.24203/ajas.v10i5.6951

Keywords:

Euler-Lagrange equation; potential energy; energy structure equation; energy components; independent components; quasi-static path

Abstract

The Euler-Lagrange equation can be used for a variety of the thermal processes from microscopic and macroscopic points of view [1-3]. In this case, the main challenge is calculating the potential energy using the Lagrangian density. Since the energy structure equation has the effects of the second law of thermodynamics as its base, in this paper, this equation is used as potential energy for the Euler-Lagrange equation. Since the energy structure equation has been presented based on the energy components as well as independent and dependent energy components concepts, therefore, a componential reduction to the Euler-Lagrange equation will be extracted. The resultant equation will be satisfied for all independent components activated in the performed process. Also, the resultant equation can be used to investigate different paths whenever the same amount of energy is applied to the system in different conditions. Also, a quasi-static path is used as a reference path.

References

T. Mengesha, Q. Du, Characterization of function spaces of vector fields and an application in nonlinear peridynamics, Nonlinear Anal. 140 (2016) 82–111.

S. Oterkus, E. Madenci, A. Agwai, Peridynamic thermal diffusion, J. Comput. Phys. 265 (2014) 71–96.

E. Madenci, E. Oterkus, Peridynamic theory and its applications, 17, Springer, 2014

S.A. Silling, R.B. Lehoucq, Convergence of peridynamics to classical elasticity theory, J. Elast. 93 (1) (2008) 13–37.

S.A. Silling, M. Epton, O. Weckner, J. Xu, E. Askari, Peridynamic states and constitutive modeling, J. Elast. 88 (2) (2007) 151–184.

Shahsavari, Saeed, et al. "A Note on the Energy Structure Theory and Development for 2D Viscoelasticity." Asian Journal of Applied Sciences (ISSN: 2321–0893) 9.1 (2021).‏

Shahsavari, Saeed. "On the Probability in General Physics from the Perspective of the Energy Structure." Asian Journal of Applied Sciences (ISSN: 2321–0893) 9.1 (2021).‏

Shahsavari, Saeed, Mehran Moradi, "A Study of the Entropy Production in Physical Processes from a New Perspective of the Energy Structure." Asian Journal of Applied Sciences (ISSN: 2321–0893) 8.6 (2020).‏

Shahsavari, Saeed, Mehran Moradi, and Morteza Esmaeilpour. "On the Irreversibility in Mechanical Systems Using a New Macroscopic Energy Structure Modeling." Asian Journal of Applied Sciences (ISSN: 2321–0893) 8.6 (2020).‏

Shahsavari, Saeed, Mehran Moradi, and Morteza Esmaeilpour. "On the Available Work Limits at Constant Heat and Entropy Production." Asian Journal of Applied Sciences (ISSN: 2321–0893) 8.6 (2020).‏

Shahsavari, Saeed, Mehran Moradi, " An Applied Component Modeling to the Irreversibility from a New Configurationally Perspective of the Statistical Physics." Asian Journal of Fuzzy and Applied Mathematics (ISSN: 2321 – 564X) 8.3 (2020).

Shahsavari, Saeed, Mehran Moradi, " Application of an Innovate Energy Balance to Investigate Viscoelastic Problems." Asian Journal of Engineering and Technology (ISSN: 2321 – 2462) 8.4 (2020).

Eu, Byung C. "Kinetic theory and irreversible thermodynamics." NASA STI/Recon Technical Report A 93 (1992).

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Published

2022-11-04

How to Cite

A Componential Reduction to the Euler-Lagrange Equation Using Energy Structure Theory. (2022). Asian Journal of Applied Sciences, 10(5). https://doi.org/10.24203/ajas.v10i5.6951

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