Generalized thermoelastic heat conduction model involving three different fractional operators

• Autorzy: Saidi Anouar , Yahya Ahmed M. H , Abouelregal Ahmed E. , Dargail Husam E. , Ahmed Ibrahim-Elkhalil , Ali Elsiddeg , Mohammed F. A.

Identyfikatory

DOI

10.2478/adms-2023-0009

• Języki publikacji: EN

Abstrakty

EN

The purpose of this paper is to introduce a new time-fractional heat conduction model with three-phase-lags and three distinct fractional-order derivatives. We investigate the introduced model in the situation of an isotropic and homogeneous solid sphere. The exterior of the sphere is exposed to a thermal shock and a decaying heat generation rate. We recuperate some earlier thermoelasticity models as particular cases from the proposed model. Moreover, the effects of different fractional thermoelastic models and the effect of instant time on the physical variables of the medium are studied. We obtain the numerical solutions for the various physical fields using a numerical Laplace inversion technique. We represent the obtained results graphically and discuss them. Physical views presented in this article may be useful for the design of new materials, bio-heat transfer mechanisms between tissues and other scientific domains.

Słowa kluczowe

EN

thermoelasticity; fractional order; three phase lags; solid sphere

PL

termoelastyczność; rząd ułamkowy; opóźnienie trójfazowe

• Wydawca: Politechnika Gdańska
• Czasopismo: Advances in Materials Science
• Rocznik: 2023
• Tom: Vol. 23, nr 2(76)
• Strony: 25--44
• Opis fizyczny: Bibliogr. 79 poz., rys., tab., wykr.

Twórcy

autor

Saidi Anouar

• Department of Mathematics, College of Science and Arts of Gurayyat, Jouf University, Gurayyat, Kingdom of Saudi Arabia

autor

Yahya Ahmed M. H

• Department of Mathematics, College of Science and Arts of Gurayyat, Jouf University, Gurayyat, Kingdom of Saudi Arabia
• Department of Mathematics, Faculty of Science and Technology, Shendi University, Shendi, Sudan

autor

Abouelregal Ahmed E.

• Department of Mathematics, College of Science and Arts of Gurayyat, Jouf University, Gurayyat, Kingdom of Saudi Arabia
• Department of Mathematics, Faculty of Science, Mansoura University, Mansoura, 35516, Egypt

autor

Dargail Husam E.

• Department of Mathematics, College of Science and Arts of Gurayyat, Jouf University, Gurayyat, Kingdom of Saudi Arabia
• Department of Mathematics, Faculty of Science and Technology, Shendi University, Shendi, Sudan

autor

Ahmed Ibrahim-Elkhalil

• Department of Mathematics, College of Science and Arts of Gurayyat, Jouf University, Gurayyat, Kingdom of Saudi Arabia
• Department of Mathematics, Faculty of Science and Technology, Shendi University, Shendi, Sudan

autor

Ali Elsiddeg

• Department of Mathematics, Taif University Faculty of Science, Kingdom of Saudi Arabia

autor

Mohammed F. A.

• Department of Mathematics, College of Science and Arts of Gurayyat, Jouf University, Gurayyat, Kingdom of Saudi Arabia
• Department of Mathematics, Faculty of Science, South Valley University, Qena, Egypt

Bibliografia

• 1. Neumann F.E.: Vorlesungen über die theorie der elasticität der festen körper und des lichtäthers, Leipzig B.G. Teubner, 1885.
• 2. Duhamel J.H.: Second mémoire sur les phénomènes thermo-mécaniques. Journal de L'Ecole Polytechnique 15(25) (1837) 1-57.
• 3. Biot M.A.: Thermoelasticity and irreversible thermodynamics. Journal of Applied Physics 27(3) (1956) 240–253.
• 4. Cattaneo C.: Sur une forme de l’équation de la chaleur éliminant le paradoxe d’une propagation instantanée. Comptes Rendus de l’Académie des Sciences 247 (1958) 431–433.
• 5. Cattaneo C.: Sulla Condizione Del Calore. Atti del Seminario Matematico e Fisico dell'Università di Modena e Reggio Emilia 3 (1948) 83-101.
• 6. Vernotte P.: Les paradoxes de la théorie continue de l'équation de la chaleur. Comptes Rendus de l’Académie des Sciences 246 (1958) 3154–3155.
• 7. Lord H.W. and Shulman Y.: A generalized dynamic theory of thermoelasticity. Journal of the Mechanics and Physics of Solids 15(5) (1967) 299–309.
• 8. Green A.E. and Lindsay K.A.: Thermoelasticity. Journal of Elasticity 2(1) (1972) 1–7.
• 9. Tzou D.Y.: A unified approach for heat conduction from macro-to micro-scales. Journal of Heat Transfer 117(1) (1995) 8–16.
• 10. Tzou D.Y.: The generalized lagging response in small-scale and high-rate heating. International Journal of Heat and Mass Transfer 38(17) (1995) 3231–3240.
• 11. Tzou D.Y.: Experimental support for the lagging behavior in heat propagation. Journal of Thermophysics and Heat Transfer 9(4) (1995) 686–693.
• 12. Antaki P.: Solution for non-Fourier dual phase lag heat conduction in a semi-infinite slab with surface heat flux. International Journal of Heat and Mass Transfer 41(14) (1998) 2253-2258.
• 13. Jiang F.M., Liu D.Y. and Zhou J.H.: Non-Fourier heat conduction phenomena in porous material heated by microsecond laser pulse. Nanoscale and Microscale Thermophysical Engineering 6(4) (2003) 331-346.
• 14. Zhou J. H., Chen J. K., and Zhang Y.W.: Dual-phase lag effects on thermal damage to biological tissues caused by laser irradiation. Computers in Biology & Medicine 39(3) (2009) 286-293.
• 15. Zhang Y. W.: Generalized dual-phase lag bioheat equations based on nonequilibrium heat transfer in living biological tissues. International Journal of Heat and Mass Transfer 52(21-22) 2009 4829-4834,.
• 16. Lee H.L., Chen W.L., Chang W.J., Wei E.J. and Yang Y.C.: Analysis of dual-phase-lag heat conduction in short-pulse laser heating of metals with a hybrid method. Applied Thermal Engineering 52(2) 2013 275-283.
• 17. Green A.E. and Naghdi P.M.: A Re-Examination of the basic postulates of thermomechanics Proceedings: Mathematical and Physical Sciences 432(1885) (1991) 171–194.
• 18. Green A.E. and Naghdi P.M.: On undamped heat waves in an elastic solid. Journal of Thermal Stresses 15(2) (1992) 253–264.
• 19. Green A.E. and Naghdi P.M.: Thermoelasticity without energy dissipation. Journal of Elasticity 31(3) (1993) 189–208.
• 20. Roychoudhuri S.: On a thermoelastic three-phase-lag model. Journal of Thermal Stresses 30(3) (2007) 231–238.
• 21. Sprague G. H. and Huang P. C.: Behavior of Aircraft Structures under Thermal Stress. SAE Transactions 66 (1958) 457–465.
• 22. Buettner K.J.K.: Thermal stresses in the modern aircraft. Archiv für Meteorologie, Geophysik und Bioklimatologie, Serie B 5 (1954) 377–387.
• 23. Loveless E. and Boswell A.C.: The Problem of Thermal Stresses in Aircraft Structures: A Paper Presented at the Bristol Conference on Thermal Stress Organized by the Stress Analysis Group of the Institute of Physics on January 7, 1954, Aircraft Engineering and Aerospace Technology 26(4) (1954) 122-124.
• 24. Rolfes R. Teßmer J. and Rohwer K.: Models and Tools for Heat Transfer, Thermal Stresses and Stability of Composite Aerospace Structures. Journal of Thermal Stresses 26 (2003) 641-670.
• 25. Capey E.C.: Alleviation of thermal stresses in aircraft structures. Aeronautical Research Council Current Papers Ministry of Aviation; Royal Aircraft Establishment; RAE Farnborough (1965).
• 26. Baczynski Z.F. and Ignaczak: Thermoelastic stress analysis of reactor secondary containment. J. Boley, B.A. [ed.], Netherlands: North-Holland 1977.
• 27. Alujevic A., Cernej B., Potrc I. and Skerget L.: Boundary element method for thermoelasticity of nuclear reactors. ETAN '81: 25 Conference of the Society for Electronics, Telecommunications, Computers, Automation, and Nuclear Engineering, Yugoslavia: Society for Electronics, Telecommunications, Automation, and Nuclear Engineering (1981).
• 28. Yuan B., Zheng J., Wang J., Zeng H., Yang W., Huang H. and Zhang S. Numerical Calculation Scheme of Neutronics-Thermal Mechanical Coupling in Solid State Reactor Core Based on Galerkin Finite Element Method. Energies 16 (2023) 659.
• 29. Hoffman R.E. and Ariman, T.: Thermal and mechanical stresses in nuclear reactor vessels. Nuclear Engineering and Design 20(1) (1972) 31-55.
• 30. Leccese G., Bianchi D., Betti B., Lentini D. and Nasuti F.: Convective and Radiative Wall Heat Transfer in Liquid Rocket Thrust Chambers. Journal of Propulsion and Power 34(2) (2018) 318–326.
• 31. Chryssolouris G.: Laser machining, theory and practice. Springer, New York, 1991.
• 32. Dominiczak K., Rzadkowski R. and Radulski W.: Thermoelastic Steam Turbine Rotor Control Based on Neural Network. In: Pennacchi, P. (ed.) Proceedings of the 9th IFToMM International Conference on Rotor Dynamics. Mechanisms and Machine Science, 21. Springer, Cham (2015).
• 33. Dominiczak K. and Banaszkiewicz M.: A verification approach to thermoelastic steam turbine rotor analysis during transient operation. Transactions IFFM 131 (2016) 55–65.
• 34. Banaszkiewicz M. and Badur J.: Practical Methods for Online Calculation of Thermoelastic Stresses in Steam Turbine Components. Selected Problems of Contemporary Thermomechanics. InTech. (2018).
• 35. Pertz G. H. and Gerhardt C. J.: Leibnizens gesammelte Werke, Lebinizens mathematische Schriften, Erste Abtheilung, Band II, 301-302. Dritte Folge Mathematik (Erster Band). A. Asher & Comp., Briefwechsel zwischen Leibniz, Hugens van Zulichem und dem Marquis de l'Hospital, 1849.
• 36. Lacroix S.F.: Traité du calcul différentiel et du calcul intégral Tome 2. Paris: Courcier, 1814.
• 37. Liouville J.: Mémoire sur le calcul des différentielles à indices quelconques. Journal de l'École polytechnique 13 (21. cah.) (1832) 71–162.
• 38. Liouville J.: Memoire sur l'integration des equations différentielles à indices fractionnaires. Journal de l'École polytechnique 15(55) (1837) 58-84.
• 39. Fourier J.: Théorie analytique de la chaleur, Paris, 1822.
• 40. Riemann B.: Versuch einer allgemeinen Auffassung der Integration und Differentiation. Gesammelte Mathematische Werke und Wissenschaftlicher Nachlass. Teubner, Leipzig 1876 (Dover, New York, 1953) 331-344.
• 41. Sonin N.Y.: On differentiation with arbitrary index. Moscow, Matematicheskii Sbornik 6(1) (1869) 1-38.
• 42. Laurent H.: Sur le calcul des dérivées à indices quelconques. Nouvelles Annales de Mathématiques 3(3) (1884) 240-252.
• 43. Grunwald A. K.: Uber "begrenzte" Derivationen und deren Anwendung. Zeitschrift für angewandte Mathematik und Physik 12 (1867) 441-480.
• 44. Weyl H.: Bemerkungen zum Begriff des Differentialquotienten gebrochener Ordnung. Vierteljahresschrift der Naturforsch. Ges. Zürich, 62 (1917) 296.
• 45. Lazarevi M.: Advanced topics on applications of fractional calculus on control problems. System Stability and Modeling, WSEAS Press, Belgrade, Serbia, 2012.
• 46. Machado J. A. T.: Fractional Calculus: Application in control and robotics. Advances in Mobile Robotics (2008).
• 47. Ferreira N., Duarte F., Lima M., Marcos M. and Machado J.A.T.: Application of fractional calculus in the dynamical analysis and control of mechanical manipulators. Fractional Calculus and Applied Analysis 11(1) (2008) 91-113.
• 48. Henry B. and Wearne S.: Existence of Turing instabilities in a two-species fractional reaction–diffusion system. SIAM Journal on Applied Mathematics 62 (2002) 870–887.
• 49. Metzler, R. and Klafter J.: The random walk’s guide to anomalous diffusion: a fractional dynamics approach. Physics Reports 339 (2000) 1-77.
• 50. Engheia N.: On the role of fractional calculus in electromagnetic theory. IEEE Antennas and Propagation Magazine 39 (1997) 35-46.
• 51. Ionescu C., Lopes A., Copot D., Machado J. A. T. and Bates J. H. T.: The role of fractional calculus in modeling biological phenomena: A review. Communications in Nonlinear Science and Numerical Simulation 51 (2017) 141–159.
• 52. Schiesse H., Metzlert R., Blument A. and Nonnemacher T.F.: Generalized viscoelastic models: their fractional equations with solutions. Journal of Physics A: Mathematical and General 28 (1995) 6567-6584.
• 53. Heymans N. and Bauwens J.-C.: Fractal rheological models and fractional differential equations for viscoelastic behavior. Rheologica Acta 33 (1994) 210–219.
• 54. Povstenko Y.Z.: Fractional heat conduction equation and associated thermal Stresses. Journal of Thermal Stresses 28 (2005) 83–102.
• 55. Povstenko Y.Z.: Fractional radial heat conduction in an infinite medium with a cylindrical cavity and associated thermal stresses. Mechanics Research Communications 37 (2010) 436–440.
• 56. Youssef H. M.: Theory of Fractional Order Generalized Thermoelasticity. Journal of Heat Transfer 132(6) (2010) 061301.
• 57. Sherief H.H., El-Sayed A.M.A. and Abd El-Latief A.M.: Fractional order theory of thermoelasticity. International Journal of Solids and Structures 47 (2010) 269–275.
• 58. Xu H., Wang X. and Qi H.: Fractional dual-phase-lag heat conduction model for laser pulse heating, 29th Chinese Control And Decision Conference (CCDC), (2017).
• 59. Xu H. and Jiang X.: Time fractional dual-phase-lag heat conduction equation. Chinese Physics B 24 (3) (2015) .
• 60. Ezzat M. A., El Karamany A. S. and Fayik M. A.: Fractional order theory in thermoelastic solid with three-phase lag heat transfer. Archive of Applied Mechanics 82(4) (2012) 557-572.
• 61. Abouelregal A. E.: Three-phase-lag thermoelastic heat conduction model with higher-order time-fractional derivatives. Indian Journal of Physics 94 (2020)1949–1963.
• 62. Quintanilla R. and Racke R.: A note on stability in three-phase-lag heat conduction. International Journal of Heat and Mass Transfer 51 (2008) 24–29.
• 63. Quintanilla R.: A well-posed problem for the three-dual-phase-lag heat conduction, Journal of Thermal Stresses 32(12) (2009) 1270–1278.
• 64. Chiriţă S., D’Apice C. and Zampoli V.: The time differential three-phase-lag heat conduction model: thermodynamic compatibility and continuous dependence. International Journal of Heat and Mass Transfer 102 (2016) 226-232.
• 65. Xu M. and Tan W.: Intermediate processes and critical phenomena: Theory, method and progress of fractional operators and their applications to modern mechanics. Science In China Series G-Physics Astronomy 49 (2006) 257–272.
• 66. Klafter J., Sokolov I.M.: Anomalous diffusion spreads its wings. Physics World 18 (2008) 29–32.
• 67. Li H.B. and Li Z.: Anomalous energy diffusion and heat conduction in one-dimensional system. Chinese Physics B 19(5) 2010.
• 68. Kilbas A.A., Srivastava H. M. and Trujillo J.J.: Theory and Applications of Fractional Differential Equations. North-Holland Mathematics Studies 204 (2006) 69-133.
• 69. Machado J.T., Kiryakova V. and Mainardi F.: Recent history of fractional calculus. Communications in Nonlinear Science and Numerical Simulation 16 (2011) 1140–1153.
• 70. Podlubny I.: Fractional Differential Equations, Academic Press, New York, 1999.
• 71. Hetnarski R.B. and Eslami M.R.: Basic Laws of Thermoelasticity. In: Thermal Stresses –Advanced Theory and Applications. Solid Mechanics and its Applications, 158. Springer, Dordrecht, 2019, pp.1-43.
• 72. Giraud A. and Rousset, G. Thermoelastic and thermoplastic response of a porous space submitted to a decaying heat source. International Journal for Numerical and Analytical Methods in Geomechanics 19(7) (1995) 475–495.
• 73. Claesson, J. and Probert, T.: Thermoelastic stress due to a rectangular heat source in a semi-infinite medium. Presentation of an analytical solution. Engineering Geology 49(3-4) (1998) 223–229.
• 74. Lebedev N. N.: Special functions and their applications. Translated from the Russian by R. A. Silverman. Englewood Cliffs, N.J.: Prentice Hall, Inc. (1965).
• 75. Dubner H. and Abate J.: Numerical inversion of Laplace transforms by relating them to the finite Fourier cosine transform. Journal of the ACM, 15(1) (1968) 115–123.
• 76. Sokolnikoff I.S.: Mathematical Theory of Elasticity, New York, Dover, 1946.
• 77. Thomas L.C: Fundamentals of Heat Transfer, Prentice-Hall Inc., Englewood Cliffs, New Jersey, 1980.
• 78. Abouelregal A. E.: Fractional heat conduction equation for an infinitely generalized thermoelastic long solid cylinder. International Journal for Computational Methods in Engineering Science and Mechanics 17(5-6) 2016 374–381.
• 79. Aouadi M.: A problem for an infinite elastic body with a spherical cavity in the theory of generalized thermoelastic diffusion. International Journal of Solids and Structures 44(17) (2007) 5711–5722.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).