Analytical solution of time fractional Cattaneo heat equation for finite slab under pulse heat flux

doi:10.1007/s10483-018-2375-8

Applied Mathematics and Mechanics (English Edition) ›› 2018, Vol. 39 ›› Issue (10): 1465-1476.doi: https://doi.org/10.1007/s10483-018-2375-8

Analytical solution of time fractional Cattaneo heat equation for finite slab under pulse heat flux

Guangying XU, Jinbao WANG

School of Port and Transportation Engineering, Zhejiang Ocean University, Zhoushan 316022, Zhejiang Province, China

收稿日期:2018-01-29 修回日期:2018-04-07 出版日期:2018-10-01 发布日期:2018-10-01
通讯作者: Jinbao WANG E-mail:jinbaow@zjou.edu.cn
基金资助:
Project supported by the National Natural Science Foundation of China (No. 11372281), the Science and Technology Plan Project of Zhoushan (No. 2016C41009), and the Innovative Team Project of Zhejiang Ocean University

Analytical solution of time fractional Cattaneo heat equation for finite slab under pulse heat flux

Guangying XU, Jinbao WANG

School of Port and Transportation Engineering, Zhejiang Ocean University, Zhoushan 316022, Zhejiang Province, China

Received:2018-01-29 Revised:2018-04-07 Online:2018-10-01 Published:2018-10-01
Contact: Jinbao WANG E-mail:jinbaow@zjou.edu.cn
Supported by:
Project supported by the National Natural Science Foundation of China (No. 11372281), the Science and Technology Plan Project of Zhoushan (No. 2016C41009), and the Innovative Team Project of Zhejiang Ocean University

摘要/Abstract

摘要： A fractional Cattaneo model is derived for studying the heat transfer in a finite slab irradiated by a short pulse laser. The analytical solutions for the fractional Cattaneo model, the classical Cattaneo-Vernotte model, and the Fourier model are obtained with finite Fourier and Laplace transforms. The effects of the fractional order parameter and the relaxation time on the temperature fields in the finite slab are investigated. The results show that the larger the fractional order parameter, the slower the thermal wave. Moreover, the higher the relaxation time, the slower the heat flux propagates. By comparing the fractional order Cattaneo model with the classical Cattaneo-Vernotte and Fourier models, it can be found that the heat flux predicted using the fractional Cattaneo model always transports from the high temperature to the low one, which is in accord with the second law of thermodynamics. However, the classical Cattaneo-Vernotte model shows that the unphysical heat flux sometimes transports from the low temperature to the high one.

关键词: finite slab, mode II crack, near crack line analysis method, crack line, elastic-plastic boundary, matching conditions, fractional Cattaneo model, Cattaneo-Vernotte model, fractional derivative

Abstract: A fractional Cattaneo model is derived for studying the heat transfer in a finite slab irradiated by a short pulse laser. The analytical solutions for the fractional Cattaneo model, the classical Cattaneo-Vernotte model, and the Fourier model are obtained with finite Fourier and Laplace transforms. The effects of the fractional order parameter and the relaxation time on the temperature fields in the finite slab are investigated. The results show that the larger the fractional order parameter, the slower the thermal wave. Moreover, the higher the relaxation time, the slower the heat flux propagates. By comparing the fractional order Cattaneo model with the classical Cattaneo-Vernotte and Fourier models, it can be found that the heat flux predicted using the fractional Cattaneo model always transports from the high temperature to the low one, which is in accord with the second law of thermodynamics. However, the classical Cattaneo-Vernotte model shows that the unphysical heat flux sometimes transports from the low temperature to the high one.

Key words: fractional derivative, mode II crack, near crack line analysis method, crack line, elastic-plastic boundary, matching conditions, Cattaneo-Vernotte model, fractional Cattaneo model, finite slab

中图分类号:

35R10
26A33

Guangying XU, Jinbao WANG. Analytical solution of time fractional Cattaneo heat equation for finite slab under pulse heat flux[J]. Applied Mathematics and Mechanics (English Edition), 2018, 39(10): 1465-1476.

参考文献

[1] KÖRNER, C. and BERGMANN, H. W. The physical defects of the hyperbolic heat conduction equation. Applied Physics A, 67, 397-401(1998)
[2] JOSEPH, D. D. and PREZIOSI, L. Heat waves. Reviews of Modern Physics, 61, 41-73(1989)
[3] ZHANG, Z. and LIU, D. Y. Advances in the study of non-Fourier heat conduction (in Chinese). Advance Mechanics, 30, 446-456(2000)
[4] ALQAHTANI, H. and YILBAS, B. S. Closed solution of Cattaneo equation including volumetric source in relation to laser short-pulse heating. Canadian Journal of Physics, 89(7), 761-767(2011)
[5] HOASHI, E., YOKOMINE, T., SHIMIZU, A., and KUNUGI, T. Numerical analysis of wave type heat transfer propagating in a thin foil irradiated by short-pulsed laser. International Journal of Heat and Mass Transfer, 46, 4083-4095(2003)
[6] AI, X. and LI, B. Q. Numerical simulation of thermal wave propagation during laser processing of thin films. Journal of Electronic Materials, 34(5), 583-591(2005)
[7] BLACKWELL, B. F. Temperature profile in semi-infinite body with exponential source and convective boundary condition. Journal of Heat Transfer, 112, 567-571(1990)
[8] ZUBAIR, S. M. and CHAUDHRY, M. A. Heat conduction in a semi-infinite solid due to timedependent laser source. International Journal of Heat and Mass Transfer, 39, 3067-3074(1996)
[9] LAM, T. T. A unified solution of several heat conduction models. International Journal of Heat and Mass Transfer, 56, 653-666(2013)
[10] LAM, T. T. and FONG, E. Application of solution structure theorem to non-Fourier heat conduction problems:analytical approach. International Journal of Heat and Mass Transfer, 54, 4796-4806(2011)
[11] CATTANEO, C. Sur une forme de l'équation de la chaleur eliminant le paradoxe d'une propagation instantanée. Comptes Rendus, 247, 431-433(1958)
[12] VERNOTTE, P. Les paradoxes de la théorie continue de l'équation de la chaleur. Comptes Rendus, 246, 3154-3155(1958)
[13] NARAYANAMURTI, V. and DYNES, R. C. Observation of second sound in bismuth. Physical Review Letters, 28(22), 1461-1465(1972)
[14] JIANG, F. M., LIU, D. Y., and ZHOU, J. H. Non-Fourier heat conduction phenomena in porous material heated by microsecond laser pulse. Microscale Thermophysical Engineering, 6, 331-346(2002)
[15] XU, G. Y. and WU, X. F. Numerical simulation of temperature profiles in the finite thickness materials shocked by the pulse heat flux on the hyperbolic equation (in Chinese). Journal of Basic Science and Engineering, 11(1), 65-70(2003)
[16] CHAVES, A. S. A fractional diffusion equation to describe Lévy flights. Physics Letter A, 239, 13-16(1998)
[17] PARADISI, P., CESARI, R., MAINARDI, F., and TAMPIERI, F. The fractional Fick's law for non-local transport processes. Physica A, 293, 130-142(2001)
[18] HILFER, R. Applications of Fractional Calculus in Physics, World Scientific, Singapore (2000)
[19] SCHIESSEL, H., METZLER, R., BLUMEN, A., and NONNENMACHER, T. F. Generalized viscoelastic models:their fractional equation with solution. Journal of Physics A:Mathematical and General, 28, 6567-6584(1995)
[20] ZHENG, L. C., LIU, Y. Q., and ZHANG, X. X. Slip effects on MHD flow of a generalized OldroydB fluid with fractional derivative. Nonlinear Analysis:Real World Applications, 13, 513-525(2012)
[21] 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, 4829-4834(2009)
[22] COMPTE, A. and METZLER, R. The generalized Cattaneo equation for the description of anomalous transport processes. Journal of Physics A:Mathematical and General, 30(21), 7277-7289(1997)
[23] POVSTENKO, Y. Fractional Cattaneo-type equations and generalized thermoelasticity. Journal of Thermal Stresses, 34, 97-114(2011)
[24] QI, H. T., XU, H. Y., and GUO, X. W. The Cattaneo-type time fractional heat conduction equation for laser heating. Computers and Mathematics with Applications, 66, 824-831(2013)
[25] JIANG, X. Y. and QI, H. T. Thermal wave model of bioheat transfer with modified RiemannLiouville fractional derivative. Journal of Physics A:Mathematical and Theoretical, 45(48), 485101(2012)
[26] XU, G. Y., WANG, J. B., and HAN, Z. Study on the transient temperature field based on the fractional heat conduction equation for laser heating (in Chinese). Applied Mathematics and Mechanics, 36, 844-849(2015)
[27] XU, H. Y., QI, H. T., and JIANG, X. Y. Fractional Cattaneo heat equation on a semi-infinite medium. Chinese Physics B, 22, 014401(2013)
[28] QI, H. T. and GUO, X. W. Transient fractional heat conduction with generalized Cattaneo model. International Journal of Heat and Mass Transfer, 76, 535-539(2014)
[29] MISHR, T. N. and RAI, K. N. Numerical solution of FSPL heat conduction equation for analysis of thermal propagation. Applied Mathematics and Computation, 273, 1006-1017(2016)
[30] ZHU, L. L. and ZHENG, X. J. A theory for electromagnetic heat conduction and a numerical model based on Boltzmann equation. International Journal of Nonlinear Science and Numerical Simulation, 7(3), 339-344(2006)
[31] CHEN, G. Ballistic-diffusion heat conduction equation. Physical Review Letters, 86(11), 2297-2300(2001)
[32] GHAZIZADEH, H. R., MAEREFAT, M., and AZIMI, A. Explicit and implicit finite difference schemes for fractional Cattaneo equation. Journal of Computational Physics, 229(19), 7042-7057(2010)
[33] PODLUBNY, I. Fractional Differential Equations, Academic Press, New York (1999)

Analytical solution of time fractional Cattaneo heat equation for finite slab under pulse heat flux

Analytical solution of time fractional Cattaneo heat equation for finite slab under pulse heat flux

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	Yue LIU, Zhen ZHAO, Yanni ZHANG, Jing PANG. Approximate solutions to fractional differential equations[J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(10): 1791-1802.
[2]	Yanli QIAO, Xiaoping WANG, Huanying XU, Haitao QI. Numerical analysis for viscoelastic fluid flow with distributed/variable order time fractional Maxwell constitutive models[J]. Applied Mathematics and Mechanics (English Edition), 2021, 42(12): 1771-1786.
[3]	Wenjie ZHAO, Shaopu YANG, Guilin WEN, Xuehong REN. Fractional-order visco-plastic constitutive model for uniaxial ratcheting behaviors[J]. Applied Mathematics and Mechanics (English Edition), 2019, 40(1): 49-62.
[4]	Yaqing LIU, Boling GUO. Coupling model for unsteady MHD flow of generalized Maxwell fluid with radiation thermal transform[J]. Applied Mathematics and Mechanics (English Edition), 2016, 37(2): 137-150.
[5]	刘小靖王记增王晓敏周又和. Exact solutions of multi-term fractional diffusion-wave equations with Robin type boundary conditions[J]. Applied Mathematics and Mechanics (English Edition), 2014, 35(1): 49-62.
[6]	何桂添;罗懋康. Dynamic behavior of fractional order Duffing chaotic system and its synchronization via singly active control[J]. Applied Mathematics and Mechanics (English Edition), 2012, 33(5): 567-582.
[7]	黄凤辉郭柏灵. General solutions to a class of time fractional partial differential equations[J]. Applied Mathematics and Mechanics (English Edition), 2010, 31(7): 815-826.
[8]	易志坚赵朝华杨庆国彭凯黄宗明. General forms of elastic-plastic matching equations for mode-III cracks near crack line[J]. Applied Mathematics and Mechanics (English Edition), 2009, 30(5): 549-559.
[9]	王成;吴承平. ELASTIC-PLASTIC ANALYTICAL SOLUTIONS FOR AN ECCENTRIC CRACK LOADED BY TWO PAIRS OF ANTI-PLANE POINT FORCES[J]. Applied Mathematics and Mechanics (English Edition), 2003, 24(7): 782-790.
[10]	朱正佑;李根国;程昌钧. A NUMERICAL METHOD FOR FRACTIONAL INTEGRAL WITH APPLICATIONS[J]. Applied Mathematics and Mechanics (English Edition), 2003, 24(4): 373-384.
[11]	朱正佑;李根国;程昌钧. QUASI-STATIC AND DYNAMICAL ANALYSIS FOR VISCOELASTIC TIMOSHENKO BEAM WITH FRACTIONAL DERIVATIVE CONSTITUTIVE RELATION[J]. Applied Mathematics and Mechanics (English Edition), 2002, 23(1): 1-12.
[12]	根国;朱正佑;程昌钧. DYNAMICAL STABILITY OF VISCOELASTIC COLUMN WITH FRACTIONAL DERIVATIVE CONSTITUTIVE RELATION[J]. Applied Mathematics and Mechanics (English Edition), 2001, 22(3): 294-303.
[13]	易志坚;严波. GENERAL FORM OF MATCHING EQUATION OF ELASTIC-PLASTIC FIELD NEAR CRACK LINE FOR MODEⅠCRACK UNDER PLANE STRESS CONDITION[J]. Applied Mathematics and Mechanics (English Edition), 2001, 22(10): 1173-1182.
[14]	王成;张录坤. NEAR CRACK LINE ELASTIC-PLASTIC ANALYSIS FOR A FINITE PLATE LOADED BY TWO PAIRS OF ANTIPLANE POINT FORCES[J]. Applied Mathematics and Mechanics (English Edition), 1998, 19(6): 547-553.
[15]	易志坚;王士杰. EXACT SOLUTIONS OF NEAR CRACK LINE FIELDS FOR MODE I CRACK UNDER PLANE STRESS CONDITION IN AN ELASTIC-PERFECTLY PLASTIC SOLID[J]. Applied Mathematics and Mechanics (English Edition), 1996, 17(4): 351-358.