On the weak solutions to the equations of a compressible heat conducting gas

Chiodaroli, Elisabetta; Feireisl, Eduard; Kreml, Ondřej

Chiodaroli, Elisabetta ; Feireisl, Eduard ; Kreml, Ondřej

Annales de l'I.H.P. Analyse non linéaire, Tome 32 (2015), p. 225-243 / Harvested from Numdam

Résumé

We consider the weak solutions to the Euler–Fourier system describing the motion of a compressible heat conducting gas. Employing the method of convex integration, we show that the problem admits infinitely many global-in-time weak solutions for any choice of smooth initial data. We also show that for any initial distribution of the density and temperature, there exists an initial velocity such that the associated initial-value problem possesses infinitely many solutions that conserve the total energy.

Publié le : 2015-01-01

MR 3303948 | Zbl 1315.35160

DOI : https://doi.org/10.1016/j.anihpc.2013.11.005

@article{AIHPC_2015__32_1_225_0,
     author = {Chiodaroli, Elisabetta and Feireisl, Eduard and Kreml, Ond\v rej},
     title = {On the weak solutions to the equations of a compressible heat conducting gas},
     journal = {Annales de l'I.H.P. Analyse non lin\'eaire},
     volume = {32},
     year = {2015},
     pages = {225-243},
     doi = {10.1016/j.anihpc.2013.11.005},
     mrnumber = {3303948},
     zbl = {1315.35160},
     language = {en},
     url = {http://dml.mathdoc.fr/item/AIHPC_2015__32_1_225_0}
}

Chiodaroli, Elisabetta; Feireisl, Eduard; Kreml, Ondřej. On the weak solutions to the equations of a compressible heat conducting gas. Annales de l'I.H.P. Analyse non linéaire, Tome 32 (2015) pp. 225-243. doi : 10.1016/j.anihpc.2013.11.005. http://gdmltest.u-ga.fr/item/AIHPC_2015__32_1_225_0/

Bibliographie

[1] T. Alazard, Low Mach number flows and combustion, SIAM J. Math. Anal. 38 no. 4 (2006), 1186 -1213 | MR 2274479 | Zbl 1121.35092

[2] T. Alazard, Low Mach number limit of the full Navier–Stokes equations, Arch. Ration. Mech. Anal. 180 (2006), 1 -73 | MR 2211706 | Zbl 1108.76061

[3] H. Amann, Nonhomogeneous linear and quasilinear elliptic and parabolic boundary value problems, Function Spaces, Differential Operators and Nonlinear Analysis, Friedrichroda, 1992, Teubner-Texte Math. vol. 133 , Teubner, Stuttgart (1993), 9 -126 | MR 1242579 | Zbl 0810.35037

[4] S. Bianchini, A. Bressan, Vanishing viscosity solutions of nonlinear hyperbolic systems, Ann. Math. (2) 161 no. 1 (2005), 223 -342 | MR 2150387 | Zbl 1082.35095

[5] A. Bressan, Hyperbolic Systems of Conservation Laws. The One Dimensional Cauchy Problem, Oxford University Press, Oxford (2000) | MR 1816648 | Zbl 0997.35002

[6] A. Bressan, F. Flores, On total differential inclusions, Rend. Semin. Mat. Univ. Padova 92 (1994), 9 -16 | Numdam | MR 1320474 | Zbl 0821.35158

[7] A. Cellina, On the differential inclusion $x^{'} \in [- 1, 1]$ , Atti Accad. Naz. Lincei, Rend. Cl. Sci. Fis. Mat. Nat. 69 (1980), 1 -6 | MR 641583 | Zbl 0922.34009

[8] E. Chiodaroli, A counterexample to well-posedness of entropy solutions to the compressible Euler system, Preprint, 2012. | MR 3261301

[9] B. Dacorogna, P. Marcellini, General existence theorems for Hamilton–Jacobi equations in the scalar and vectorial cases, Acta Math. 178 (1997), 1 -37 | MR 1448710 | Zbl 0901.49027

[10] C.M. Dafermos, Hyperbolic Conservation Laws in Continuum Physics, Springer-Verlag, Berlin (2000) | MR 1763936 | Zbl 0940.35002

[11] C. De Lellis, L. Székelyhidi, On admissibility criteria for weak solutions of the Euler equations, Arch. Ration. Mech. Anal. 195 no. 1 (2010), 225 -260 | MR 2564474 | Zbl 1192.35138

[12] C. De Lellis, L. Székelyhidi, The h-principle and the equations of fluid dynamics, Bull. Am. Math. Soc. (N.S.) 49 no. 3 (2012), 347 -375 | MR 2917063 | Zbl 1254.35180

[13] E. Feireisl, Relative entropies in thermodynamics of complete fluid systems, Discrete Contin. Dyn. Syst., Ser. A 32 (2012), 3059 -3080 | MR 2912071 | Zbl 1245.80002

[14] E. Feireisl, A. Novotný, Singular Limits in Thermodynamics of Viscous Fluids, Birkhäuser Verlag, Basel (2009) | MR 2499296 | Zbl 1176.35126

[15] E. Feireisl, A. Novotný, Weak-strong uniqueness property for the full Navier–Stokes–Fourier system, Arch. Ration. Mech. Anal. 204 (2012), 683 -706 | MR 2909912 | Zbl 1285.76034

[16] B. Kirchheim, Rigidity and geometry of microstructures, http://www.mis.mpg.de/publications/other-series/ln/~lecturenote-1603.html (2003)

[17] N.V. Krylov, Parabolic equations with VMO coefficients in Sobolev spaces with mixed norms, J. Funct. Anal. 250 no. 2 (2007), 521 -558 | MR 2352490 | Zbl 1133.35052

[18] T.P. Liu, Admissible solutions of hyperbolic conservation laws, Mem. Am. Math. Soc. 30 no. 240 (1981) | MR 603391 | Zbl 0446.76058

[19] S. Müller, V. Šverák, Convex integration for Lipschitz mappings and counterexamples to regularity, Ann. Math. (2) 157 no. 3 (2003), 715 -742 | MR 1983780 | Zbl 1083.35032

[20] D. Serre, Local existence for viscous system of conservation laws: $H^{s}$ -data with $s > 1 + d / 2$ , Nonlinear Partial Differential Equations and Hyperbolic Wave Phenomena, Contemp. Math. vol. 526 , Amer. Math. Soc., Providence, RI (2010), 339 -358 | Zbl 1223.35230

[21] D. Serre, The structure of dissipative viscous system of conservation laws, Physica D 239 no. 15 (2010), 1381 -1386 | MR 2658332 | Zbl 1193.37012

[22] A. Shnirelman, Weak solutions of incompressible Euler equations, Handbook of Mathematical Fluid Dynamics, vol. II, North-Holland, Amsterdam (2003), 87 -116 | MR 1983590 | Zbl 1143.76394

[23] C.H. Wilcox, Sound Propagation in Stratified Fluids, Appl. Math. Ser. vol. 50 , Springer-Verlag, Berlin (1984) | MR 742932 | Zbl 0543.76107