On self-similar solutions of time and space fractional sub-diffusion equations

In this paper, we have considered two different sub-diffusion equations involving Hilfer, hyper-Bessel and Erd´elyi-Kober fractional derivatives. Using a special transformation, we equivalently reduce the considered boundary value problems for fractional partial differential equation to the corresponding problems for ordinary differential equation. An essential role is played by certain properties of Erd´elyi-Kober integral and differential operators. We have applied also successive iteration method to obtain self-similar solutions in an explicit form. The obtained self-similar solutions are represented by generalized Wright type function. We have to note that the usage of imposed conditions is important to present self-similar solutions via given data.

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[1] Kilbas A.A., Srivastava H.M. & Trujillo J.J. (2006). Theory and Applications of fractional differential equations, Amsterdam: Elsevier.
[2] Singh J. (2020). Analysis of fractional blood alcohol model with composite fractional derivative. Chaos, Solitons and Fractals, 140, 110127.
[3] Singh J., Kumar D. & Baleanu D. (2020). A new analysis of fractional fish farm model associated with Mittag-Leffler-type kernel. International Journal of Biomathematics, 13(2), 2050010.
[4] Karimov, E.T. (2020). Frankl-Type Problem for a Mixed Type Equation with the Caputo Fractional Derivative. Lobachevskii Journal of Mathematics 41, 1829–1836.
[5] Uchaikin, V.V. Fractional Derivatives for Physicists and Engineers, Volume I Background and Theory Volume II Applications, Springer, 2013.
[6] Buckwar, E., Luchko, Y. (1998). Invariance of a partial differential equation of fractional order under the Lie group of scaling transformations. Journal of Mathematical Analysis and Applications, 227(1), 81-97.
[7] Stanyukovich, K.P. Unsteady Motion of Continuous Media, Oxford: Pergamon Press, 1959.
[8] Barenblatt, G. I.Scaling, self-similarity, and intermediate asymptotics: dimensional analysis and intermediate asymptotics (No. 14). Cambridge University Press, 1996.
[9] Luchko, Y. & Gorenflo, R. (1998). Scaleinvariant solutions of a partial differential equation of fractional order. Fractional Calculus and Applied Analysis, 1(1), 63-78.
[10] Basti B. & Benhamidouche N. (2020). Existence results of self-similar solutions to the Caputo-types space-fractional heat equation. Surveys in Mathematics and its Applications, 15, 153-168.
[11] Gazizov, R.K., Kasatkin, A.A. & Lukashchuk, S. Y. (2007). Continuous transformation groups of fractional differential equations. Vest. USATU, 9, 125-135.
[12] Gazizov, R. K., Kasatkin, A. A. & Lukashchuk, S. Y. (2009). Symmetry properties of fractional diffusion equations. Physica Scripta, 2009(136), 014016.
[13] Duan, J. S., Guo, A. P. & Yun, W. Z. (2014). Similarity solution for fractional diffusion equation. Abstract and Applied Analysis, Article ID 548126, 1-5.
[14] Silver Costa, F., Marao, J.A.P.F., AlvesSoares, J.C. & Capelas de Oliveira, E. (2015). Similarity solution to fractional nonlinear space-time diffusion-wave equation. Journal of Mathematical Physics, 3 (2015), 033507.
[15] Bakkyaraj T. & Sahadevan R. (2015). Group formalism of Lie transformations to timefractional partial differential equations, Pramana. Journal of Physics, 85(5), 845-860.
[16] Ruzhansky M. & Hasanov A. (2020). SelfSimilar Solutions of Some Model Degenerate Partial Differential Equations of the Second, Third, and Fourth Order, Lobachevskii Journal of mathematics, 41, 1103-1114.
[17] Garra, R., Giusti, A., Mainardi, F., & Pagnini, G. (2014). Fractional relaxation with time-varying coefficient. Fractional Calculus and Applied Analysis, 17(2), 424-439.
[18] Garra, R., Orsingher, E., & Polito, F. (2015). Fractional diffusions with time-varying coefficients. Journal of Mathematical Physics, 56(9), 093301.
[19] Al-Musalhi F., Al-Salti N. & Karimov E.T. (2018). Initial boundary value problems for a fractional differential equation with hyperBessel operator, Fractional Calculus and Applied Analysis 21(1), 200-219.
[20] Karimov, E. T. & Toshtemirov, B. H. (2019). Tricomi type problem with integral conjugation condition for a mixed type equation with the hyper-bessel fractional differential operator. Bulletin of the Institute of Mathematics, (4), 9-14.
[21] Pagnini, G. (2012). Erd´elyi-Kober fractional diffusion. Fractional calculus and applied analysis, 15(1), 117-127.
[22] Yuldashev T.K. & Kadirkulov B.J. (2020). Nonlocal problem for a mixed type fourthorder differential equation with Hilfer fractional operator. Ural mathematical journal, 6(1), 153–167.
[23] Hilfer, R., Luchko, Y. & Tomovski, Z. (2009). Operational method for the solution of fractional differential equations with generalized Riemann-Liouville fractional derivatives. Fractional Calculus and Applied Analysis, 12(3), 299-318.
[24] Furati, K. M. & Kassim, M. D. (2012). Existence and uniqueness for a problem involving Hilfer fractional derivative. Computers and Mathematics with Applications, 64(6), 1616- 1626.
[25] Luchko, Y. & Trujillo, J. (2007). Caputo-type modification of the Erd´elyi-Kober fractional derivative. Fractional Calculus and Applied Analysis, 10(3), 249-267.
[26] Hanna, L. M. & Luchko, Y. F. (2014). Operational calculus for the Caputo-type fractional Erd´elyi-Kober derivative and its applications. Integral Transforms and Special Functions, 25(5), 359-373.
[27] Garra, R., Giusti, A., Mainardi, F. & Pagnini, G. (2014). Fractional relaxation with time-varying coefficient. Fractional Calculus and Applied Analysis, 17(2), 424–439.
[28] Gorenflo, R., Luchko, Y., & Mainardi, F. (2000). Wright functions as scale-invariant solutions of the diffusion-wave equation. Journal of Computational and Applied Mathematics, 118(1-2), 175-191.

An International Journal of Optimization and Control: Theories & Applications (IJOCTA)-Cover

ISSN: 2146-0957
Yayın Aralığı: Yılda 2 Sayı
Yayıncı: Prof. Dr. Ramazan YAMAN

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