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Self-similar shock wave solutions for heat conductions in solids and for non-linear Maxwell equations Imre Ferenc Barna & Robert Kersner 1) Wigner Research.

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Presentation on theme: "Self-similar shock wave solutions for heat conductions in solids and for non-linear Maxwell equations Imre Ferenc Barna & Robert Kersner 1) Wigner Research."— Presentation transcript:

1 Self-similar shock wave solutions for heat conductions in solids and for non-linear Maxwell equations Imre Ferenc Barna & Robert Kersner 1) Wigner Research Center of the Hungarian Academy of Sciences 2) ELI-HU Nonprofit Kft 3) University of Pécs, PMMK Department of Mathematics and Informatics 1,2 3

2 Outline Introduction (physically relevant solutions for PDEs) Motivation (infinite propagation speed with the diffusion/heat equation) A way-out (Cattaneo equ. OR using a hyperbolic first order PDE system Heat conduction model with a non-linear Cattaneo-Vernot law The non-linear Maxwell equation with self-similar shock wave solutions Summary

3 Important kind of solutions for non-linear PDEs - Travelling waves: arbitrary wave fronts u(x,t) ~ g(x-ct), g(x+ct) - Self-similar solutions Sedov, Barenblatt, Zeldovich gives back the Gaussian for heat conduction

4 Ordinary diffusion/heat conduction equation U(x,t) temperature distribution Fourier law + conservation law parabolic PDA, no time-reversal sym. strong maximum principle ~ solution is smeared out in time the fundamental solution: general solution is: kernel is non compact = inf. prop. speed Problem from a long time  But have self-similar solution

5 Our alternatives Way 1 Def. new kind of time-dependent Cattaneo law (with physical background) new telegraph-type equation with self-similar and compact solutions I.F. Barna and R. Kersner, http://arxiv.org/abs/1002.099 J. Phys. A: Math. Theor. 43, (2010) 375210 Way 2 instead of a 2 nd order parabolic(?) PDA use a first order hyperbolic PDA system with 2 Eqs. these are not equivalent!!! non-continuous solutions shock waves

6 Cattaneo heat conduction equ. Cattaneo heat conduction law, new term Energy conservation law T(x,t) temperature distribution q heat flux k effective heat conductivity heat capacity relaxation time Telegraph equation(exists in Edyn., Hydrodyn.)

7 General properties of the telegraph eq. solution decaying travelling waves Bessel function Problem: 1) no self-similar diffusive solutions 2)oscillations, T<0 ? maybe not the best eq.

8 Self-similar, non-continous shock wave behaviour for heat- propagation (Way 2) general Cattaneo heat conduction law, + cylindrically symmetric conservation law heat conduction coefficient (temperature dependent e.q. plasmas) relaxation time also temperature dependent (e.q. plasma phys.) using the first oder PDA system (not second order) looking for self-similar solutions in the form

9 Way to the solutions The ODE system for the shape functions: The second eq. can be integrated getting the relation: The following universality relations are hold: Form of the solutions: Note the dependence representing different physics

10 The solutions The final ODE reads: Just putting: Getting: which is linear in y

11 The solutions The direction field of the solutions for y and for the inverse function for eta Arrow shows how the inverse function were defined CUT and 0 solution

12 How the shock propagates in time

13 The solutions The corresponding ODE : solution for the shape function: Returning to original variables: And the final analytic and continous solutions are:

14 Summary of the solutions

15 Idea is similar: instead of the second order wave equation we investigate the two coupled first-order Maxwell PDEs in one dimension with a non-linear power-law material or constitutive equation depending on the exponent (meaning different material and physics) Having continous or shock wave solutions The second example

16 The Maxwell equations & non-linearity The field equations of Maxwell The constitutive Eqs + differential Ohm’s Law Our consideration, power law : But:

17 Geometry & Applied Ansatz

18 The final ordinary differential equations Universality relations among the parameters: The first equ. is a total difference so can be integrated : Remaining a simple ODE with one parameter q (material exponent): ’ means derivation with respect to eta

19 Different kind of solutions Non-compact solutions for q > -1 Compact solutions for q < -1 shock-waves No closed-forms are available so the direction fields are presented

20 Physically relevant solutions We consider the Poynting vector which gives us the energy flux (in W/m^2) in the field Unfortunatelly, there are two contraversial definition of the Poynting vector in media, unsolved problem R.N. Pfeifer et al. Rev. Mod. Phys. 79 (2007) 1197. published: I.F. Barna Laser Phys. 24 (2014) 086002 & arXiv : http://arxiv.org/abs/1303.7084 http://arxiv.org/abs/1303.7084

21 we presented physically important, self -similar solutions for various PDEs which can describe shock waves as a first example we investigated a genaralized one dimensional Cattaneo-Vernot heat conduction problem as a second example we investigated the 1 dim. Maxwell equations (instead fo the wave equation) closing with non-linear (power law) constitutive equations In both cases we found shock-wave solutions for different material constants Summary

22 Questions, Remarks, Comments?…

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