Ecole doctorale de Physique de la région Parisienne (ED107)

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196 Bibliographie Cooper, L. N., Mills, R. L., Sessler, A. M., Possible Superfluidity of a System of Strongly Interacting Fermions, Physical Review, 114 : 1377–1382 (1959). Cowling, T. G., The non-radial oscillations of polytropic stars, Mon. Not. of the Royal Astron. Soc., 101 : 367–375 (1941). Cox, J. P., Theory of stellar pulsation, Research supported by the National Science Foundation Princeton, Princeton University Press, 393 pages (1980). Cutler, C., Lindblom, L., The effect of viscosity on neutron star oscillations, ApJ , 314 : 234–241 (1987). Damour, T., Esposito-Farèse, G., Gravitational-wave versus binary-pulsar tests of strong-field gravity, Physical Review D, 58 : 42001, 12 pages (1998). Deruelle, N., Piran, T. (eds.), Gravitational radiation (1983), Proceedings of the Advanced Study Institute, Les Houches, Haute-Savoie, France, June 2-21, 1982, 510 pages. Dintrans, B., Rieutord, M., A comparison of the anelastic and subseismic approximations for low-frequency gravity modes in stars, Mon. Not. of the Royal Astron. Soc., 324 : 635–642 (2001). Einstein, A., Näherungsweise Integration der Feldgleichungen der Gravitation, Sitzber Preuss. Akad. Wiss. Berlin, pages 688–696 (1916). Einstein, A., Sitzber Preuss. Akad. Wiss. Berlin, page 154 (1918). Fierz, M., Helv. Phys. Acta, 29 : 128 (1956). Finzi, B., Att. Accad. Naz. Lincei Cl. Sc. Fois. Mat. Nat., 6 : 18 (1949). Friedman, J. L., Lockitch, K., Implications of the r-mode instability of rotating relativistic stars, Gurzadyan, V., Jantzen, R., Ruffini, R. (eds.), Proceedings of the 9th Marcel Grossman Meeting, World Scientific, pages 166–184 (2002). Friedman, J. L., Morsink, S. M., Axial Instability of Rotating Relativistic Stars, ApJ , 502 : 714–720 (1998). Friedman, J. L., Schutz, B. F., Gravitational radiation instability in rotating stars, ApJ, Lett., 199 : L157–L159 (1975a). Friedman, J. L., Schutz, B. F., On the stability of relativistic systems, ApJ , 200 : 204–220 (1975b). Friedman, J. L., Schutz, B. F., Lagrangian perturbation theory of nonrelativistic fluids, ApJ , 221 : 937–957 (1978a). Friedman, J. L., Schutz, B. F., Secular instability of rotating Newtonian stars, ApJ , 222 : 281–296 (1978b). Friman, B. L., Maxwell, O. V., Neutrino emissivities of neutron stars, ApJ , 232 : 541–557 (1979). Gamow, G., Schoenberg, M., Neutrino Theory of Stellar Collapse, Physical Review, 59 : 539–547 (1941).
Bibliographie 197 Glendenning, N. K., Phase transitions and crystalline structures in neutron star cores, Phys. Rep., 342 : 393–447 (2001). Gold, T., Rotating neutron stars as the origin of the pulsating radio sources, Nature, 218 : 731–732 (1968). Goldreich, P., Julian, W. H., Pulsar Electrodynamics, ApJ , 157 : 869–880 (1969). Gottlieb, D., Orszag, S. A., Numerical Analysis of spectral Methods : Theory and Applications, Society for Industrial and Applied Mathematics, 172 pages, Philadelphia (1977). Gourgoulhon, E., Have strange quark stars been discovered ?, SF2A-2002 : Semaine de l’Astrophysique Francaise (2002). Gourgoulhon, E., Grandclément, P., Taniguchi, K., Marck, J.-A., Bonazzola, S., Quasiequilibrium sequences of synchronized and irrotational binary neutron stars in general relativity : Method and tests, Physical Review D, 63 : 64029, 27 pages (2001). Gressman, P., Lin, L. M., Suen, W. M., Stergioulas, N., Friedman, J. L., Nonlinear r-modes in neutron stars : Instability of an unstable mode, Physical Review D, 66 : 041303, 5 pages (2002). Guyon, E., Hulin, J.-P., Petit, L., Hydrodynamique physique, InterEditions, 506 pages, Paris (1991). Haensel, P., communication privée (1980). Haensel, P., Non-equilibrium neutrino emissivities and opacities of neutron star matter, A&A, 262 : 131–137 (1992). Haensel, P., Solid interiors of neutron stars, Marck, J.-A., Lasota, J.-P. (eds.), Astrophysical Sources of Gravitational Radiation, Les Houches, pages 129–149 (1997). Haensel, P., Neutron Star Crusts, Blaschke, D., Glendenning, N. K., Sedrakian, A. (eds.), LNP Vol. 578 : Physics of Neutron Star Interiors, ECT ⋆ , Springer, pages 127–174 (2001). Haensel, P., communication privée (2002). Haensel, P., Levenfish, K. P., Yakovlev, D. G., Bulk viscosity in superfluid neutron star cores. I. Direct Urca processes in npemu matter, A&A, 357 : 1157–1169 (2000). Haensel, P., Levenfish, K. P., Yakovlev, D. G., Bulk viscosity in superfluid neutron star cores. II. Modified Urca processes in npemu matter, A&A, 372 : 130–137 (2001). Haensel, P., Levenfish, K. P., Yakovlev, D. G., Bulk viscosity in superfluid neutron star cores. III. Effects of Σ − hyperons, A&A, 381 : 1080–1089 (2002). Haensel, P., Pichon, B., Experimental nuclear masses and the ground state of cold dense matter, A&A, 283 : 313–318 (1994). Haensel, P., Zdunik, J. L., A submillisecond pulsar and the equation of state of dense matter, Nature, 340 : 617–619 (1989).
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Ecole doctorale de Physique de la r
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Table des matières Résumé v Abst
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TABLE DES MATIÈRES iii 4.5.2 Noise
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Résumé Résumé v Cette étude tr
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Abstract Abstract vii This study de
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Introduction Les sens dont l’a do
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Introduction 3 même, leurs observa
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Chapitre 1 Relativité générale e
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1.1 Relativité générale 1.1.1 Gr
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1.1 Relativité générale 9 La rel
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1.1.3 Tests et prédictions 1.1 Rel
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1.2 Ondes gravitationnelles 1.2.1 E
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y 1.2 Ondes gravitationnelles 15 x
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1.3 Sources d’ondes gravitationne
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1.4 Détection 23 Figure 1.6 - Sens
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¢¡ £ © ¥ ¢¡ £ © ¤ ¢¡ £
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Chapitre 2 Etoiles à neutrons Somm
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2.1 Naissance d’une étoile à ne
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2.1 Naissance d’une étoile à ne
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astre Terre Soleil naine blanche é
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2.2 Structure interne 35 Figure 2.4
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2.2 Structure interne 37 extensions
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2.2 Structure interne 39 Figure 2.5
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2.2 Structure interne 41 rigidité
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2.2 Structure interne 43 où = h/2
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2.2 Structure interne 45 à des fer
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2.2 Structure interne 47 Type de su
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2.3 Principes de l’évolution d
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est environ 0.7 fois la masse nue 1
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Log 10 (T/10 9 K) 0 -0.5 -1 -1.5 -2
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2.4 Superfluidité et écarts à l
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aboutit à 2.4 Superfluidité et é
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Résultats 2.4 Superfluidité et é
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Chapitre 3 Oscillations stellaires
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3.1 Modes d’une étoile à neutro
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3.1.2 Perturbations 3.1 Modes d’u
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Un mode propre vérifie donc 3.1 Mo
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3.1 Modes d’une étoile à neutro
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3.2 Oscillations d’une étoile re
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Ω c /Ω max 1.00 0.98 0.96 0.94
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3.3 Modes inertiels et r-modes 97 F
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P K /P 1.0 0.8 0.6 0.4 0.2 3.3 Mode
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3.3 Modes inertiels et r-modes 101
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Chapitre 4 Inertial modes in slowly
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4.1 Introduction 105 what is done w
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4.2 Equations and numbers 107 obvio
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4.2 Equations and numbers 109 tenso
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4.2 Equations and numbers 111 4.2.2
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or 4.2 Equations and numbers 113 Tv
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4.3 Mass conservation, boundary con
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4.4 Test and calibration of the cod
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4.4 Test and calibration of the cod
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Sp(V θ ) 1 4.4 Test and calibratio
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E(t) / E 0 1.15 1.1 1.05 1 4.4 Test
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Sp(S xx ) S xx 0.1 0 -0.1 4.4 Test
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V r Sp(V r ) 0.4 0.2 0 -0.2 -0.4 -0
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4.5.1 Modifications 4.5 Differentia
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Sp(V r ) V r 4 2 0 -2 4.5 Different
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4.6 Strong Cowling approximation in
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V θ Sp(V θ ) 10 5 0 -5 -10 4.6 St
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can be written 4.6 Strong Cowling a
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E Polar / E Total 0.05 0.04 0.03 0.
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S xx Sp(S xx ) 0.2 0.1 0 -0.1 4.6 S
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GW emission. 4.8 Acknowledgments 4.
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Page 177 and 178: 5.3 Résultats numériques 165 Il e
Page 179 and 180: 5.4 Conclusions 167 Spectres de pui
Page 181 and 182: Conclusions et perspectives “Pour
Page 183 and 184: Remerciements 171 La liste est long
Page 185 and 186: Appendice A Géométrie différenti
Page 187 and 188: A.3 Métrique et variétés (pseudo
Page 189 and 190: Appendice B Spectral methods and ve
Page 191 and 192: B.1 Spirit of the spectral methods
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Page 195 and 196: B.2 Solving Euler or Navier-Stokes
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Page 199 and 200: Liste des tableaux Etoiles à neutr
Page 201 and 202: Table des figures Relativité gén
Page 203 and 204: TABLE DES FIGURES 191 4.14 Time evo
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Page 215 and 216: Bibliographie 203 Ruoff, J., Stavri
Page 218: Cette étude traite de différents
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