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Legendre wavelet residual approach for moving boundary problem with variable thermal physical properties

  • Jitendra , Vikas Chaurasiya , Kabindra Nath Rai and Jitendra Singh EMAIL logo
Published/Copyright: October 19, 2022
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International Journal of Nonlinear Sciences and Numerical Simulation
From the journal International Journal of Nonlinear Sciences and Numerical Simulation Volume 23 Issue 7-8

Abstract

The main aim of the current article is to describe an uni-dimensional moving boundary problem with conduction and convection effect when thermal conductivity and specific heat varying linearly with temperature and time. The Mathematical model has nonlinearity due to presence of variable thermal conductivity and specific heat. A Legendre wavelet residual approach is introduced to get the solution of the problem with high accuracy. The surface heat flux is taken as an exponent function of time while latent heat is presented as an exponent function of position. Galerkin technique is used to obtain the numerical solution in case of constant physical properties while collocation technique is used for variable thermal physical properties. When it is considered that thermal physical properties are constant then obtained numerical solution was compared with exact solution and found in good acceptance. The effect of convection and variable thermal conductivity with time and temperature on the location of the moving layer thickness is analyzed. Further the effect of Peclet number and other physical parameters on the location of moving layer thickness are discussed in detail.

Keywords: Legendre wavelet residual technique; moving boundary problem; Peclet number; phase change material; variable thermal physical properties
2010 Mathematics Subject Classification: 35K05; 35R37; 80A22; 65T60; 35K61
Corresponding author: Jitendra Singh, Department of Mathematics, Institute of Science, Banaras Hindu University, Varanasi 221005, India, E-mail:

Acknowledgments

Jitendra, one of the author is grateful to C.S.I.R. (India) in the form of UGC Senior Research Fellowship vide Ref. No. 30-09-2015-433013 (i) RAC/RES/March.2016/S-8/dated 29/8/2017 for this research work. Vikas Chaurasiya, one of the authors is grateful to DST-New Delhi (India) for the senior Research Fellowship vide Ref. No. DST/INSPIRE/03/2017/000184 (i) Ref. no/Math/2017–18/March 18/347 for this research work.

  1. Author contribution: All the authors have accepted responsibility for the entire content of this submitted manuscript and approved submission.

  2. Research funding: None declared.

  3. Conflict of interest statement: The authors declare no conflicts of interest regarding this article.

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Received: 2019-03-01
Revised: 2020-06-03
Accepted: 2022-09-23
Published Online: 2022-10-19
Published in Print: 2022-12-16

© 2022 Walter de Gruyter GmbH, Berlin/Boston

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https://doi.org/10.1515/ijnsns-2019-0076
Keywords for this article
Legendre wavelet residual technique; moving boundary problem; Peclet number; phase change material; variable thermal physical properties

Articles in the same Issue

  1. Frontmatter
  2. Original Research Articles
  3. Coordinated target tracking in sensor networks by maximizing mutual information
  4. Legendre wavelet residual approach for moving boundary problem with variable thermal physical properties
  5. Computational study of intravenous magnetic drug targeting using implanted magnetizable stent
  6. Extended logistic map for encryption of digital images
  7. Valuation of the American put option as a free boundary problem through a high-order difference scheme
  8. Power minimization of gas transmission network in fully transient state using metaheuristic methods
  9. A priori error estimates for finite element approximations to transient convection-diffusion-reaction equations in fluidized beds
  10. Higher order rogue waves for the(3 + 1)-dimensional Jimbo–Miwa equation
  11. Dynamic characteristics of supersonic turbulent free jets from four types of circular nozzles
  12. New insights into singularity analysis
  13. Chaos and bifurcations in a discretized fractional model of quasi-periodic plasma perturbations
  14. Wavelet collocation methods for solving neutral delay differential equations
  15. Numerical solution of highly non-linear fractional order reaction advection diffusion equation using the cubic B-spline collocation method
  16. Solving nonlinear third-order boundary value problems based-on boundary shape functions
  17. Positive radial solutions for Dirichlet problems involving the mean curvature operator in Minkowski space
  18. Effect of outlet impeller diameter on performance prediction of centrifugal pump under single-phase and cavitation flow conditions
  19. A fractional-order ship power system: chaos and its dynamical properties
  20. Graphical structure of extended b-metric spaces: an application to the transverse oscillations of a homogeneous bar
  21. Hypergeometric fractional derivatives formula of shifted Chebyshev polynomials: tau algorithm for a type of fractional delay differential equations
  22. Modelling and numerical synchronization of chaotic system with fractional-order operator
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