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Generalized Four-momentum for Continuously Distributed Materials

Year 2024, , 1509 - 1538, 01.09.2024
https://doi.org/10.35378/gujs.1231793

Abstract

A four-dimensional differential Euler-Lagrange equation for continuously distributed materials is derived based on the principle of least action, and instead of Lagrangian, this equation contains the Lagrangian density. This makes it possible to determine the density of generalized four-momentum in covariant form as derivative of the Lagrangian density with respect to four-velocity of typical particles of a system taken with opposite sign, and then calculate the generalized four-momentum itself. It is shown that the generalized four-momentum of all typical particles of a system is an integral four-vector and therefore should be considered as a special type of four-vectors. The presented expression for generalized four-momentum exactly corresponds to the Legendre transformation connecting the Lagrangian and Hamiltonian. The obtained formulas are used to calculate generalized four-momentum of stationary and moving relativistic uniform systems for the Lagrangian with particles and vector fields, including electromagnetic and gravitational fields, acceleration field and pressure field. It turns out that the generalized four-momentum of a moving system depends on the total mass of particles, on the Lorentz factor and on the velocity of the system’s center of momentum. Besides, an additional contribution is made by the scalar potentials of the acceleration field and the pressure field at the center of system. The direction of the generalized four-momentum coincides with the direction of four-velocity of the system under consideration, while the generalized four-momentum is part of the relativistic four-momentum of the system.

References

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  • [2] Mekhitarian, V.M., “The invariant representation of generalized momentum”, Journal of Contemporary Physics, 47(6): 249-256, (2012).
  • [3] Kienzler, R., Herrmann, G., “On the four-dimensional formalism in continuum mechanics”, Acta Mechanica, 61: 103-125, (2003).
  • [4] Goldstein, H., Poole, C.P., Safko, J.L., “Classical Mechanics”, Third Edition, Addison-Wesley, (2001).
  • [5] Fedosin, S.G., “About the cosmological constant, acceleration field, pressure field and energy”, Jordan Journal of Physics, 9(1): 1-30, (2016).
  • [6] Fedosin, S.G., “The Procedure of Finding the Stress-Energy Tensor and Equations of Vector Field of Any Form”, Advanced Studies in Theoretical Physics, 8(18): 771-779, (2014).
  • [7] Fedosin, S.G., “Two components of the macroscopic general field”, Reports in Advances of Physical Sciences, 1(2): 1750002, (2017).
  • [8] Fedosin, S.G., “The Principle of Least Action in Covariant Theory of Gravitation”, Hadronic Journal, 35(1): 35-70, (2012).
  • [9] Fedosin, S., “The physical theories and infinite hierarchical nesting of matter”, Volume 2, LAP LAMBERT Academic Publishing, (2015).
  • [10] Einstein, A., Infeld, L., Hoffmann, B., “The Gravitational Equations and the Problem of Motion”, Annals of Mathematics, Second Series, 39(1): 65-100, (1938).
  • [11] Fedosin, S.G., “Four-Dimensional Equation of Motion for Viscous Compressible and Charged Fluid with Regard to the Acceleration Field, Pressure Field and Dissipation Field”, International Journal of Thermodynamics, 18(1): 13-24, (2015).
  • [12] Fedosin, S.G., “Estimation of the physical parameters of planets and stars in the gravitational equilibrium model”, Canadian Journal of Physics, 94(4): 370-379, (2016).
  • [13] Fock, V.A., “The Theory of Space, Time and Gravitation”, London: Pergamon Press, (1959).
  • [14] Dirac, P.A.M., “General theory of relativity”, Florida State University, New York - London - Sydney - Toronto: John Wiley & Sons, Inc., (1975).
  • [15] Fedosin, S.G., “Relativistic energy and mass in the weak field limit”, Jordan Journal of Physics, 8(1): 1-16, (2015).
  • [16] Fedosin, S.G., “The Gravitational Field in the Relativistic Uniform Model within the Framework of the Covariant Theory of Gravitation”, International Letters of Chemistry, Physics and Astronomy, 78: 39-50, (2018).
  • [17] Fedosin, S.G., “The Integral Energy-Momentum 4-Vector and Analysis of 4/3 Problem Based on the Pressure Field and Acceleration Field”, American Journal of Modern Physics, 3(4): 152-167, (2014).
  • [18] Searle, G.F.C., “On the steady motion of an electrified ellipsoid”, The Philosophical Magazine Series 5, 44 (269): 329-341, (1897).
  • [19] Fedosin, S.G., “4/3 Problem for the Gravitational Field”, Advances in Physics Theories and Applications, 23: 19-25, (2013).
  • [20] Fedosin, S.G., “Energy and metric gauging in the covariant theory of gravitation”, Aksaray University Journal of Science and Engineering, 2(2): 127-143, (2018).
  • [21] Fedosin, S.G., “The covariant additive integrals of motion in the theory of relativistic vector fields”, Bulletin of Pure and Applied Sciences, 37 D (2): 64-87, (2018).
  • [22] Fedosin, S.G., “The electromagnetic field in the relativistic uniform model”, International Journal of Pure and Applied Sciences, 4(2): 110-116, (2018).
  • [23] Fedosin, S.G., “Equations of motion in the theory of relativistic vector fields”, International Letters of Chemistry, Physics and Astronomy, 83: 12-30, (2019).
  • [24] Fedosin, S.G., “The potentials of the acceleration field and pressure field in rotating relativistic uniform system”, Continuum Mechanics and Thermodynamics, 33(3): 817-834, (2021).
  • [25] Rezzolla, L., Zanotti, O., “Relativistic hydrodynamics”, Oxford: Oxford University Press, (2013).
  • [26] Giulini, D., Rezzolla, L., Zanotti, O., “Relativistic hydrodynamics”, General Relativity and Gravitation, 47: 3, (2015).
  • [27] Ehlers, J., “Contributions to the relativistic mechanics of continuous media”, General Relativity and Gravitation, 25 (12): 1225-1266, (1993).
  • [28] Grot, R.A., Eringen, A.C., “Relativistic continuum mechanics: Part II – electromagnetic interactions with matter”, International Journal of Engineering Science, 4(6): 638-670, (1966).
  • [29] Salazar, J.F., Zannias, T., “On extended thermodynamics: From classical to the relativistic regime”, International Journal of Modern Physics D, 29(15): 2030010, (2020).
  • [30] Israel, W., Stewart, J.M., “Transient relativistic thermodynamics and kinetic theory”, Annals of Physics, 118 (2): 341-372, (1979).
  • [31] Ruggeri, T., Masaru, S., “Classical and Relativistic Rational Extended Thermodynamics of Gases”, Heidelberg: Springer, (2021).
  • [32] Souriau, J.M., “Thermodynamique Relativiste des Fluides”, Rendiconti del Seminario Matematico; Università Politecnico di Torino: Torino, Italy, 35: 21-34, (1978).
  • [33] de Saxcé, G., Vallee, C., “Bargmann group, momentum tensor and Galilean invariance of Clausius-Duhem inequality”, International Journal of Engineering Science, 50(1): 216-232, (2011).
  • [34] Sedov, L.I. “A course in continuum mechanics”, Volumes. I-IV, Netherland: Wolters-Noordhoff Publishing, (1971).
Year 2024, , 1509 - 1538, 01.09.2024
https://doi.org/10.35378/gujs.1231793

Abstract

References

  • [1] Landau, L.D., Lifshitz, E.M., “The Classical Theory of Fields”, Pergamon Press, (1951).
  • [2] Mekhitarian, V.M., “The invariant representation of generalized momentum”, Journal of Contemporary Physics, 47(6): 249-256, (2012).
  • [3] Kienzler, R., Herrmann, G., “On the four-dimensional formalism in continuum mechanics”, Acta Mechanica, 61: 103-125, (2003).
  • [4] Goldstein, H., Poole, C.P., Safko, J.L., “Classical Mechanics”, Third Edition, Addison-Wesley, (2001).
  • [5] Fedosin, S.G., “About the cosmological constant, acceleration field, pressure field and energy”, Jordan Journal of Physics, 9(1): 1-30, (2016).
  • [6] Fedosin, S.G., “The Procedure of Finding the Stress-Energy Tensor and Equations of Vector Field of Any Form”, Advanced Studies in Theoretical Physics, 8(18): 771-779, (2014).
  • [7] Fedosin, S.G., “Two components of the macroscopic general field”, Reports in Advances of Physical Sciences, 1(2): 1750002, (2017).
  • [8] Fedosin, S.G., “The Principle of Least Action in Covariant Theory of Gravitation”, Hadronic Journal, 35(1): 35-70, (2012).
  • [9] Fedosin, S., “The physical theories and infinite hierarchical nesting of matter”, Volume 2, LAP LAMBERT Academic Publishing, (2015).
  • [10] Einstein, A., Infeld, L., Hoffmann, B., “The Gravitational Equations and the Problem of Motion”, Annals of Mathematics, Second Series, 39(1): 65-100, (1938).
  • [11] Fedosin, S.G., “Four-Dimensional Equation of Motion for Viscous Compressible and Charged Fluid with Regard to the Acceleration Field, Pressure Field and Dissipation Field”, International Journal of Thermodynamics, 18(1): 13-24, (2015).
  • [12] Fedosin, S.G., “Estimation of the physical parameters of planets and stars in the gravitational equilibrium model”, Canadian Journal of Physics, 94(4): 370-379, (2016).
  • [13] Fock, V.A., “The Theory of Space, Time and Gravitation”, London: Pergamon Press, (1959).
  • [14] Dirac, P.A.M., “General theory of relativity”, Florida State University, New York - London - Sydney - Toronto: John Wiley & Sons, Inc., (1975).
  • [15] Fedosin, S.G., “Relativistic energy and mass in the weak field limit”, Jordan Journal of Physics, 8(1): 1-16, (2015).
  • [16] Fedosin, S.G., “The Gravitational Field in the Relativistic Uniform Model within the Framework of the Covariant Theory of Gravitation”, International Letters of Chemistry, Physics and Astronomy, 78: 39-50, (2018).
  • [17] Fedosin, S.G., “The Integral Energy-Momentum 4-Vector and Analysis of 4/3 Problem Based on the Pressure Field and Acceleration Field”, American Journal of Modern Physics, 3(4): 152-167, (2014).
  • [18] Searle, G.F.C., “On the steady motion of an electrified ellipsoid”, The Philosophical Magazine Series 5, 44 (269): 329-341, (1897).
  • [19] Fedosin, S.G., “4/3 Problem for the Gravitational Field”, Advances in Physics Theories and Applications, 23: 19-25, (2013).
  • [20] Fedosin, S.G., “Energy and metric gauging in the covariant theory of gravitation”, Aksaray University Journal of Science and Engineering, 2(2): 127-143, (2018).
  • [21] Fedosin, S.G., “The covariant additive integrals of motion in the theory of relativistic vector fields”, Bulletin of Pure and Applied Sciences, 37 D (2): 64-87, (2018).
  • [22] Fedosin, S.G., “The electromagnetic field in the relativistic uniform model”, International Journal of Pure and Applied Sciences, 4(2): 110-116, (2018).
  • [23] Fedosin, S.G., “Equations of motion in the theory of relativistic vector fields”, International Letters of Chemistry, Physics and Astronomy, 83: 12-30, (2019).
  • [24] Fedosin, S.G., “The potentials of the acceleration field and pressure field in rotating relativistic uniform system”, Continuum Mechanics and Thermodynamics, 33(3): 817-834, (2021).
  • [25] Rezzolla, L., Zanotti, O., “Relativistic hydrodynamics”, Oxford: Oxford University Press, (2013).
  • [26] Giulini, D., Rezzolla, L., Zanotti, O., “Relativistic hydrodynamics”, General Relativity and Gravitation, 47: 3, (2015).
  • [27] Ehlers, J., “Contributions to the relativistic mechanics of continuous media”, General Relativity and Gravitation, 25 (12): 1225-1266, (1993).
  • [28] Grot, R.A., Eringen, A.C., “Relativistic continuum mechanics: Part II – electromagnetic interactions with matter”, International Journal of Engineering Science, 4(6): 638-670, (1966).
  • [29] Salazar, J.F., Zannias, T., “On extended thermodynamics: From classical to the relativistic regime”, International Journal of Modern Physics D, 29(15): 2030010, (2020).
  • [30] Israel, W., Stewart, J.M., “Transient relativistic thermodynamics and kinetic theory”, Annals of Physics, 118 (2): 341-372, (1979).
  • [31] Ruggeri, T., Masaru, S., “Classical and Relativistic Rational Extended Thermodynamics of Gases”, Heidelberg: Springer, (2021).
  • [32] Souriau, J.M., “Thermodynamique Relativiste des Fluides”, Rendiconti del Seminario Matematico; Università Politecnico di Torino: Torino, Italy, 35: 21-34, (1978).
  • [33] de Saxcé, G., Vallee, C., “Bargmann group, momentum tensor and Galilean invariance of Clausius-Duhem inequality”, International Journal of Engineering Science, 50(1): 216-232, (2011).
  • [34] Sedov, L.I. “A course in continuum mechanics”, Volumes. I-IV, Netherland: Wolters-Noordhoff Publishing, (1971).
There are 34 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Physics
Authors

Sergey G. Fedosin 0000-0003-3627-2369

Early Pub Date January 25, 2024
Publication Date September 1, 2024
Published in Issue Year 2024

Cite

APA Fedosin, S. G. (2024). Generalized Four-momentum for Continuously Distributed Materials. Gazi University Journal of Science, 37(3), 1509-1538. https://doi.org/10.35378/gujs.1231793
AMA Fedosin SG. Generalized Four-momentum for Continuously Distributed Materials. Gazi University Journal of Science. September 2024;37(3):1509-1538. doi:10.35378/gujs.1231793
Chicago Fedosin, Sergey G. “Generalized Four-Momentum for Continuously Distributed Materials”. Gazi University Journal of Science 37, no. 3 (September 2024): 1509-38. https://doi.org/10.35378/gujs.1231793.
EndNote Fedosin SG (September 1, 2024) Generalized Four-momentum for Continuously Distributed Materials. Gazi University Journal of Science 37 3 1509–1538.
IEEE S. G. Fedosin, “Generalized Four-momentum for Continuously Distributed Materials”, Gazi University Journal of Science, vol. 37, no. 3, pp. 1509–1538, 2024, doi: 10.35378/gujs.1231793.
ISNAD Fedosin, Sergey G. “Generalized Four-Momentum for Continuously Distributed Materials”. Gazi University Journal of Science 37/3 (September 2024), 1509-1538. https://doi.org/10.35378/gujs.1231793.
JAMA Fedosin SG. Generalized Four-momentum for Continuously Distributed Materials. Gazi University Journal of Science. 2024;37:1509–1538.
MLA Fedosin, Sergey G. “Generalized Four-Momentum for Continuously Distributed Materials”. Gazi University Journal of Science, vol. 37, no. 3, 2024, pp. 1509-38, doi:10.35378/gujs.1231793.
Vancouver Fedosin SG. Generalized Four-momentum for Continuously Distributed Materials. Gazi University Journal of Science. 2024;37(3):1509-38.