Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-04T19:07:14.439Z Has data issue: false hasContentIssue false

X-Ray Binaries and Related Systems

Published online by Cambridge University Press:  07 August 2017

Virginia Trimble*
Affiliation:
Astronomy Department University of Maryland College Park MD 20742 USA Physics Department University of California Irvine CA 92717 USA

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Neutron stars and a few black holes in binaries reveal their presence by emitting X-rays when they accrete gas from their companions via a wind or disk. Related objects include SS 433, Geminga, gamma ray bursters, TeV/PeV sources, and the source in CTB 108. Systems with secondaries 8 Mo are the natural descendents of main sequence OB binaries. Those with secondaries ≤ 1 Mo arguably form some other way. These systems display a wealth of structure in both wavelength and time domains, much of which is reasonably well understood. Among the things we would like to know more about are the masses and rotation periods of the neutron stars in the two main kinds of systems.

Type
Invited Papers
Copyright
Copyright © Kluwer 1992 

References

Achterberg, A. 1989. Nature 342, 51 Google Scholar
Angelini, L., Stella, L. & Parmar, A.N., 1989. ApJ 346, 606 Google Scholar
Angelini, L. et al. 1991. ApJ 371, 332 Google Scholar
Bhattacharya, D. & van den Heuvel, E.P.J., 1991. Phys. Reports 203, 1 Google Scholar
Bignami, G., Caraveo, P.A., & Paul, J.A., 1988. AAp 202, L1 Google Scholar
Bisnovatyi-Kogan, G.S. 1991. AAp 245, 528 Google Scholar
Bisnovatyi-Kogan, G.S. et al. 1989. Sov. Astron. 34, 44 Google Scholar
Brown, J.C. et al. 1991. ApJ 378, 307 Google Scholar
Burnard, D.J. et al. 1991. ApJ 367, 575 CrossRefGoogle Scholar
Canal, R., Isern, J. & Labay, J., 1991. ARA&A 28, 183 Google Scholar
Carlini, A. & Treves, A., 1989. AAp 215, 283 Google Scholar
Casares, J. 1991. MNRAS 250, 712 Google Scholar
Charles, P.A. et al. 1991. MNRAS 249, 567 CrossRefGoogle Scholar
Cherepashchuk, A.M. et al. 1989. Catalogue of Close Binaries in Late Evolutionary Stages (Moscow University Press, in Russian)Google Scholar
Clark, G.W. 1975. ApJ 199, L143 CrossRefGoogle Scholar
Dermer, C.D., Hurley, K. & Hartmann, D., 1991. ApJ 370, 341 Google Scholar
Dingus, B.L. et al. 1988. PRL 60, 1785 & 61, 1906 CrossRefGoogle Scholar
Davis, S.R. & Coe, M.J. 1991. MNRAS 249, 313 Google Scholar
Dolan, J.F. & Tapia, S., 1989. ApJ 344, 830 Google Scholar
Dotani, T. et al. 1990. Nature 347, 534 Google Scholar
Eichler, D. & Ko, K., 1988. ApJ 333, 719 Google Scholar
Fabian, A.C. & Rees, M.J., 1979. MNRAS 187, 13p Google Scholar
Fabian, A.C., Pringle, J.E. & Rees, M.J. 1975. MNRAS 172, 15p CrossRefGoogle Scholar
Gnedin, Yu. N. & Ikhsanov, N.R. 1990. Sov. Astron. 34, 586 Google Scholar
Greiner, J. et al. 1991. AAp 246, L17 Google Scholar
Grindlay, J.E. 1988. IAU Symp. 126, 347 Google Scholar
Haswell, C.A. & Shafter, A.W., 1990. ApJ 359, L47 Google Scholar
van den Heuvel, E.P.J. 1981. IAU Symp. 93, 155 Google Scholar
van den Heuvel, E.P.J. & Habets, G.M.H.J., 1985. in Srinivasan, G. & Radhakrisnan, V. eds. Supernovae, Their Progenitors, and Their Remnants (Indian Academy of Sciences, Bangalore) p. 129 Google Scholar
van den Heuvel, E.P.J. & Rappaport, S.A., eds. 1991. X-Ray Binaries and the Formation of Binary and Millisecond Pulsars (NATO ASI, Kluwer)Google Scholar
Higdon, J.C. & Lingenfelter, R.E., 1990. ARA&A 28, 401 Google Scholar
Ho, C. et al. eds. 1991. Gamma Ray Burster Workshop (Cambridge Univ. P.)Google Scholar
Hunt, J. & Battrick, B., eds. 1990. 23rd ESLAB Symp: X-Ray Binaries (ESA Paris, ESA-SP-296) Google Scholar
Hut, P. et al. 1991. AAp 241, 137 Google Scholar
Illarimov, A.F. & Kompaneets, D.A., 1990. MNRAS 247, 219 Google Scholar
Indulekhar, K. 1990. A&SS 172, 1 Google Scholar
Inoue, H. 1991. Inst. of Space & Astronautical Science, RN-482 Google Scholar
Joss, P.C. & Rappaport, S.A., 1979. AAp 71, 217 Google Scholar
Katz, J.I. 1975. Nature 253, 698 Google Scholar
King, A.R. 1991. MNRAS 250, 3p Google Scholar
van der Klis, M. 1989. ARA&A 27, 517 Google Scholar
Kochanek, C.S. & Hawley, J.R., 1990. ApJ 350, 561 Google Scholar
Koyama, K. et al. 1989. PASJ 41, 461 Google Scholar
Kundt, W. 1991. Comm. Astrophys. 15, 255 Google Scholar
Lamb, D.Q. & Patterson, J., eds. 1985. Cataclysmic Variables and Low Mass X-ray Binaries (Dordrecht: Reidel)Google Scholar
Lewin, W.H.G. & van den Heuvel, E.P.J., eds. 1983. Accretion Driven X-Ray Sources (Cambridge Univ. Press)Google Scholar
Lewis, D.A. et al. 1991. ApJ 369, 479 CrossRefGoogle Scholar
Machin, G. et al. 1991. MNRAS 247, 205 Google Scholar
Madej, J. 1991. ApJ 376, 161 Google Scholar
Makishima, K. 1991. Inst. Space & Astronautical Science, RN-482 Google Scholar
Makishima, K. et al. 1990. PASJ 42, 295 Google Scholar
Margon, G. & Anderson, S.F., 1989. ApJ 347, 448 Google Scholar
Mason, K.O., Watson, M.G. & White, N.E., eds. 1986. The Physics of Accretion onto Compact Objects (Springer-Verlag, Lect. Notes in Physics)Google Scholar
Melia, F., Zylstra, G.J., & Fryxell, B., 1991. ApJ 377, L101 Google Scholar
Meyer, F. et al. eds. 1989. Theory of Accretion Diskcs (NATO ARW, Dordrecht : Kluwer)Google Scholar
Milgrom, M. 1978. AAp 67, L25 Google Scholar
Milgrom, M. 1979. AAp 76, L3; 78, L9; 78, 617 Google Scholar
Miyamoto, S. & Kitamoto, S., 1991. ApJ 374, 741 Google Scholar
Murakami, T. 1991. Inst. Space & Astronautical Science, RN-482 Google Scholar
Muraki, Y. et al. 1991. ApJ 373, 657 Google Scholar
Nagase, F. 1991. Talk at 28th Yamada Conf: Frontiers of X-Ray Astronomy Google Scholar
Paczynski, B. 1976. IAU Symp. 73, 75 Google Scholar
Paczynski, B. 1990a. ApJ 363, 218 Google Scholar
Paczynski, B. 1990b. ApJ 365, L9 Google Scholar
van Paradijs, J. et al. 1990. PASJ 42, 633 Google Scholar
Parmar, A.N. & White, N.E., 1988. Mem. Ital. Astron. Soc. 59, 147 Google Scholar