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THIN ACCRETION DISCS AROUND NEUTRON AND QUARK STARS

THIN ACCRETION DISCS AROUND NEUTRON AND QUARK STARS. T. Harko K. S. Cheng Z. Kovacs DEPARTMENT OF PHYSICS, THE UNIVERSITY OF HONG KONG, POK FU LAM ROAD, HONG KONG SAR, P.R. CHINA. CONTENT. 1. What are strange stars? 2. Basic properties of strange stars

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THIN ACCRETION DISCS AROUND NEUTRON AND QUARK STARS

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  1. THIN ACCRETION DISCS AROUND NEUTRON AND QUARK STARS T. Harko K. S. Cheng Z. Kovacs DEPARTMENT OF PHYSICS, THE UNIVERSITY OF HONG KONG, POK FU LAM ROAD, HONG KONG SAR, P.R. CHINA

  2. CONTENT 1. What are strange stars? 2. Basic properties of strange stars 3. Thin accretion discs around neutron and strange stars 4. Equations of state of neutron and quark matter 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark stars 6. Summary

  3. 1. WHAT ARE STRANGE STARS? Neutrons and protons are both composed of quarks The true ground state of the hadrons may be strange matter, not(Witten, PRD, 30, 272, 1984) Strange matter is a bulk quark matter phase consisting of: -a roughly equal numbers of up, down and strange quarks - a smaller number of electrons (to guarantee charge neutrality)

  4. Formation of quark stars • -conversion of a neutron star to a quark star due to the presence of a seed of strange matter at its core • -there are two combustion modes: deflagration (slow combustion) and detonation (fast combustion) • -conversion of proto-neutron stars formed during supernova explosion to strange stars

  5. 2. BASIC PROPERTIES OF STRANGE STARS • The properties of the strange matter are determined by the thermodynamic potentials, which are functions of the chemical potentials. • In the limit of the zero mass for the strange quark the equation of state becomes • where is the vacuum energy associated with the quark phase

  6. HOW TO IDENTIFY A STRANGE STAR? • It is very difficult to distinguish quark stars from neutron stars • There are differences in: • -radial vibrations • -maximum rotation frequency • -signals of quark deconfinement from the braking indexes of pulsars • -cooling curves

  7. PHOTON EMISSIVITY OF STRANGE MATTER • The plasma frequency of quark matter is • At low temperatures the equilibrium photon emissivity of quark matter is negligible small

  8. 2. BREMSSTRAHLUNG RADIATION FROM THE ELECTROSPHERE • The bremmstrahlung radiation from the electrosphere of the strange stars may be the main observational signature of a strange star(Jaikumar, Gale, Page & Prakash, PRD, 70, 2004, 023004) • The bremsstrahlung luminosity is well above the Eddington limit

  9. 2. Electron-positron emission of the electrosphere • The extremely strong electric field at the surface of a strange star may be a powerful source of electron-positron pairs (Usov, PRL, 80, 230, 1998) • The electron-positron luminosity is

  10. Energy fluxes emitted via different radiation mechanisms -electron-electron bremsstrahlung (solid curve),electron-positron pair creation (dotted curve),quark-quark bremsstrahlung (dashed curve), pion emission (long dashed curve),thermal photon radiation (ultra-long dashed curve)

  11. 2. BASIC PROPERTIES OF STRANGE STARS • Bulk models of strange and neutron stars are relatively similar • The most powerful method to directly observe strange stars may be via their electromagnetic emission • Surface bremsstrahlung radiation and electron-positron pair emission could lead to the observational detection of strange stars

  12. 2. BASIC PROPERTIES OF STRANGE STARS • -a possibility for indirectly detecting a quark star could be through the gravitational effect it produces on thin accretion discs (Kovacs et al., Astron. Astrophys., in press) • -rapid rotation of compact general relativistic objects modifies the geometry of the space-time around them • -the external geometry depends on the multipole moments of the star, which in turn are determined by the equation of state of the dense matter

  13. 3. Thin accretion discs around neutron and strange stars

  14. 3. Thin accretion discs around neutron and strange stars

  15. 3. Thin accretion discs around neutron and strange stars • - a thin accretion disc is a disc whose vertical size is negligible as compared to its horizontal extension • - the matter moves in Keplerian orbits around the central object • -the matter is modeled by an anisotropic fluid source (Kovacs et al., Astron. Astrophys., in press)

  16. 3. Thin accretion discs around neutron and strange stars • -the energy flux from the disc is given by -angular velocity -energy per unit mass -angular momentum per unit mass -we consider an arbitrary stationary and axially symmetric geometry

  17. 3. Thin accretion discs around neutron and strange stars • -the geodesic equations take the form must hold -for stable circular orbits, the conditions are determined by -the marginally stable orbits

  18. 3. Thin accretion discs around neutron and strange stars • -the accreted matter is considered in thermodynamic equilibrium • -the radiation emitted by the disc is a black-body radiation

  19. 4. Equations of state of neutron and quark matter • 1. Akmal-Pandharipande-Ravenhall (APR) EOS (Akmal, A. et al., 1998, Phys. Rev. C, 58, 1804) • 2. Douchin-Haensel (DH) EOS (Douchin, F., Haensel, P. 2001, Astron. Astrophys., 380, 151) • 3. Shen-Toki-Oyamatsu-Sumiyoshi (STOS) EOS (Shen, H. et al., 1998, Nucl. Phys. A, 637, 435) • 4. Relativistic Mean Field (RMF) equations of state with isovector scalar mean field (Kubis, S., Kutschera, M. 1997, Phys. Lett. B, 399, 191) • 5. Baldo-Bombaci-Burgio (BBB) EOS (Baldo, M. et al., 1997, Astron. Astrophys., 328, 274) • 6. Bag model equation of state (Q) EOS (Witten, E. 1984, Phys. Rev. D, 30, 272) • 7. Color-Flavor-Locked (CFL) EOS (Lugones, G., Horvath, J. E. 2002, Phys. Rev. D, 66, 074017).

  20. 4. Equations of state of neutron and quark matter

  21. 4. Equations of state of neutron and quark matter • -the space time geometry exterior to the star, as well as the physical parameters of the system, are computed by using the RNS code (Stergioulas, N. 2003, Living Rev. Rel., 6, 3) • -the RNS code is a fully relativistic, 3D computer code

  22. 4. Equations of state of neutron and quark matter • 1. Models with similar mass and angular velocity • 2. Models rotating at Keplerian frequencies • 3. Models with similar central densities and eccentricities

  23. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsa) models with same mass and angular velocity

  24. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsa) models with same mass and angular velocity

  25. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsa) models with same mass and angular velocity

  26. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsb) models rotating at Keplerian velocities

  27. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsb) models rotating at Keplerian velocities

  28. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsb) models rotating at Keplerian velocities

  29. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsc) models with same central density and eccentricity

  30. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsc) models with same central density and eccentricity

  31. 5. Electromagnetic signatures of accretion discs around rapidly rotating neutron and quark starsc) models with same central density and eccentricity

  32. 6. SUMMARY • The observation of strange stars would open a unique possibility for the study of the superdense quark matter and of some fundamental physical processes • Some astronomical objects like powerful accreting X-ray sources, X-ray bursters, soft gamma ray repeaters etc. may be in fact strange stars

  33. 6. SUMMARY • -the physical properties of thin accretion disc around rapidly rotating neutron and quark stars could discriminate between different types of compact objects • -due to differences in space-time structure, quark stars exhibit important differences in terms of the disc properties, as compared to neutron stars

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