194 Bibliographie Baym, G., Pethick, C. J., Suther<strong>la</strong>nd, P., The Ground State of Matter at High Densities : Equation of State and Stel<strong>la</strong>r Mo<strong>de</strong>ls, ApJ , 170 : 299–317 (1971b). Bejger, M., Yakovlev, D. G., Gnedin, O. Y., Cooling of superfluid neutron stars with muons, Acta Physica Polonica, accepted for publication, astro-ph/0210485, 10 pages (2002). Beyer, H. R., Kokkotas, K. D., On the r-mo<strong>de</strong> spectrum of re<strong>la</strong>tivistic stars, Mon. Not. of the Royal Astron. Soc., 308 : 745–750 (1999). Bildsten, L., Gravitational Radiation and Rotation of Accreting Neutron Stars, ApJ, Lett., 501 : L89–L93 (1998). B<strong>la</strong>nchet, L., Time-asymmetric structure of gravitational radiation, Physical Review D, 47 : 4392–4420 (1993). B<strong>la</strong>nchet, L., Gravitational radiation reaction and ba<strong>la</strong>nce equations to post-Newtonian or<strong>de</strong>r, Physical Review D, 55 : 714–732 (1997). B<strong>la</strong>nchet, L., Gravitational Radiation from Post-Newtonian Sources and Inspiralling Compact Binaries, Living Reviews in Re<strong>la</strong>tivity, 5, Article en ligne : http ://www.livingreviews.org/Articles/Volume5/2002-3b<strong>la</strong>nchet (2002). Bocquet, M., Bonazzo<strong>la</strong>, S., Gourgoulhon, E., Novak, J., Rotating neutron star mo<strong>de</strong>ls with a magnetic field., A&A, 301 : 757–775 (1995). Bohr, A., Mottelson, B. R., Pines, D., Possible Analogy between the Excitation Spectra of Nuclei and Those of the Superconducting Metallic State, Physical Review, 110 : 936–938 (1958). Bonazzo<strong>la</strong>, S., Gourgoulhon, E., Physics of the Sources of Gravitational Waves, Experimental Physics of Gravitational Waves, pages 62–105 (2000). Bonazzo<strong>la</strong>, S., Gourgoulhon, E., Marck, J.-A., Re<strong>la</strong>tivistic formalism to compute quasiequilibrium configurations of nonsynchronized neutron star binaries, Physical Review D, 56 : 7740–7749 (1997). Bonazzo<strong>la</strong>, S., Gourgoulhon, E., Marck, J.-A., Numerical approach for high precision 3D re<strong>la</strong>tivistic star mo<strong>de</strong>ls, Physical Review D, 58 : 104020, 14 pages (1998). Bonazzo<strong>la</strong>, S., Gourgoulhon, E., Marck, J.-A., Spectral methods in general re<strong>la</strong>tivistic astrophysics, J. of Comp. and App. Math., 109 : 433–473 (1999). Bonazzo<strong>la</strong>, S., Gourgoulhon, E., Salgado, M., Marck, J.-A., Axisymmetric rotating re<strong>la</strong>tivistic bodies : A new numerical approach for ’exact’ solutions, A&A, 278 : 421–443 (1993). Bonazzo<strong>la</strong>, S., Marck, J.-A., Three dimensional gas dynamics in a sphere, J. of Comp. Phys., 87 : 201–230 (1990). Bonazzo<strong>la</strong>, S., Marck, J.-A., Astrophysical sources of gravitational radiation, Ann. Rev. Nucl. Part. Sci., 44 : 655–717 (1994). Bondi, H., van <strong>de</strong>r Burg, M. G. J., Metzner, A. W. K., Gravitational waves in General Re<strong>la</strong>tivity VII. Waves from axisymmetric iso<strong>la</strong>ted systems, Proc. R. Soc. London A, 269 : 21–52 (1962).
Bibliographie 195 Bonnor, W. B., Spherical gravitational waves, Philos. Trans. R. Soc. London A, 251 : 233–271 (1959). Brans, C., Dicke, R. H., Mach’s Principle and a Re<strong>la</strong>tivistic Theory of Gravitation, Physical Review, 124 : 925–935 (1961). Burrows, A., Lattimer, J. M., The birth of neutron stars, ApJ , 307 : 178–196 (1986). Camilo, F., Stairs, I. H., Lorimer, D. R., Backer, D. C., Ransom, S. M., Klein, B., Wielebinski, R., Kramer, M., McLaughlin, M. A., Arzoumanian, Z., Müller, P., Discovery of Radio Pulsations from the X-Ray Pulsar J0205+6449 in Supernova Remnant 3C 58 with the Green Bank Telescope, ApJ, Lett., 571 : L41–L44 (2002). Carter, B., Killing Horizons and Orthogonally Transitive Groups in Space-Time, Journal of Mathematical Physics, 10 : 70–81 (1969). Carter, B., Mathematical foundations of the theory of re<strong>la</strong>tivistic stel<strong>la</strong>r and b<strong>la</strong>ck hole configurations, Carter, B., Hartle, J. B. (eds.), NATO Advanced Science Institutes (ASI) Series B : Physics, Proceedings of a NATO Advanced Study Institute on Gravitation in Astrophysics, held in Cargese, Corsica, July 15-31, 1986, New York : Plenum Press, 1987, edited by Carter, B. ; Hartle, J.B., pages 63–122 (1987). Carter, B., Covariant theory of conductivity in i<strong>de</strong>al fluid or solid media, Anile, A., Choquet-Bruhat, Y. (eds.), Re<strong>la</strong>tivistic fluid dynamics, Springer-Ver<strong>la</strong>g, pages 1–64 (1989). Carter, B., Re<strong>la</strong>tivistic Superfluid Mo<strong>de</strong>ls for Rotating Neutron Stars, B<strong>la</strong>schke, D., Glen<strong>de</strong>nning, N. K., Sedrakian, A. (eds.), LNP Vol. 578 : Physics of Neutron Star Interiors, ECT ⋆ , Springer, pages 54–96 (2001). Carter, B., Hartle, J. B. (eds.), Gravitation in astrophysics (1987). Chandrasekhar, S., Solutions of Two Problems in the Theory of Gravitational Radiation, Physical Review Letters, 24 : 611–615 (1970). Charikhi, M., Chesneaux, J.-M., Jezequel, F., Ricco, F., Vil<strong>la</strong>in, L., A dynamical computation of a multiple integral involved in the neutron star theory, SCAN2002 conference, Paris (France), 23-27 september 2002 (2002). Chesneaux, J.-M., Jezequel, F., Dynamical control of computations using the Trapezoidal and Simpson’s rules, Journal of Universal Computer Science, 4 : 2–10 (1998). Chiu, H., Salpeter, E. E., Surface X-Ray Emission from Neutron Stars , Physical Review Letters, 12 : 413–415 (1964). Choquet-Bruhat, Y., DeWitt-Morette, C., Dil<strong>la</strong>rd Bleick, M., Analysis, manifolds, and physics, North-Hol<strong>la</strong>nd Pub. Co., 630 pages (1982). Ciufolini, I., Fi<strong>de</strong>caro, F. (eds.), Gravitational Waves : Sources and Detectors (1997), 366 pages. Cook, G. B., Shapiro, S. L., Teukolsky, S. A., Testing a simplified version of Einstein’s equations for numerical re<strong>la</strong>tivity, Physical Review D, 53 : 5533–5540 (1996).
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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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1.3 Sources d’ondes gravitationne
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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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2.3 Principes de l’évolution d
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est environ 0.7 fois la masse nue 1
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2.3 Principes de l’évolution d
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2.3 Principes de l’évolution d
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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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2.4 Superfluidité et écarts à l
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aboutit à 2.4 Superfluidité et é
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2.4 Superfluidité et écarts à l
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2.4 Superfluidité et écarts à l
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Résultats 2.4 Superfluidité et é
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2.4 Superfluidité et écarts à l
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2.4 Superfluidité et écarts à l
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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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3.2 Oscillations d’une étoile re
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3.2 Oscillations d’une étoile re
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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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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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