This book explores cataclysmic variables with and without strong, overpowering magnetic fields. You'll read about stars with densities ranging from that of the Sun to the degenerate matter of white dwarfs to the ultra-compact states of neutron stars and black holes. One of the objects examined and discussed is the Double Pulsar, highlighting what observations have told us about fundamental physics.
E.F. Milone received a BA from Columbia and his graduate degrees (MS, PhD) in astronomy from Yale University. Since 1971 he has been in the Physics & Astronomy Department of the University of Calgary, helping to shape and direct activities at that university's Rothney Astrophysical Observatory and teaching astronomy and astrophysics courses. He retired from the Directorship in Sept. 2004, and as Professor a year later. Currently he is Professor Emeritus, RAO Director Emeritus, and Faculty Professor in the Physics & Astronomy Department, and continues his observational and analytical research on variable stars, and optical and photometry. He is Vice President of the IAU Commission 25 on Photometry and Polarimetry and Chair of that Commission's Infrared Working Group.
D.A. Leahy received a B.Sc. in Coop. Applied Physics from U. Waterloo in 1975 and M.Sc. in 1976 and Ph.D. in 1980 in Theoretical Physics from University of British Columbia. After 2 years as N.R.C. Research Associate in Space Science at NASA's Marshall Space Science Center, he returned to Canada for a 1 year Research Associate at University Calgary before taking a NSERC University Research Fellow/ Assistant Professor position in 1983. Research activities have included observing X-ray binaries and supernova remnants using balloon-borne telescopes, space based telescopes including NASA's X-ray astronomy satellites (HEAO-1, Einstein, RXTE, Chandra), Japanese satellites (GINGA, TENMA, ASCA), European satellites (EXOSAT, ROSAT, XMM-Newton), and several ground based observatories (DRAO, VLA, NOAO's Kitt Peak telescopes, and others). Theoretical work includes studies on black hole evaporation, timing analysis methods, neutron star magnetospheres, accretion flows in binaries, and quantum electrodynamics in strong magnetic fields.
D.W. Hobill has degrees from Worcester Polytechnic Institute (B.S. 1971), the University of Calgary (M.Sc -1974) and the University of Victoria (Ph.D. -1980). His postdoctoral work I ncludes a NATO Fellowship at
the Institut Henri Poincare in Paris, and positions at Stevens Institute of Technology and the University of Illinois where he later became the head of the numerical relativity group at the National Center for Supercomputing Applications.He has been in the Department of Physics and Astronomy at the University of Calgary since 1991 where his research interests are in astrophysical applications of general relativity. Specifically his research is in black hole formation. gravitational wave generation from compact objects, gravitational l lensing as a tool for exploring curved space time and anisotropic cosmologies.
Short-period binaries run the gamut from widely separated stars to black-hole pairs; in between are systems that include neutron stars and white dwarfs, and partially evolved systems such as tidally distorted and over-contact systems. These objects represent stages of evolution of binary stars, and their degrees of separation provide critical clues to how their evolutionary paths differ from that of single stars. The widest and least distorted systems provide astronomers with the essential precise data needed to study all stars: mass and radius. The interactions of binary star components, on the other hand, provide a natural laboratory to observe how the matter in these stars behaves under different and often varying physical conditions. Thus, cataclysmic variables with and without overpoweringly strong magnetic fields, and stars with densities from that found in the Sun to the degenerate matter of white dwarfs and the ultra-compact states of neutron stars and black holes are all discussed. The extensive index permits cross-referencing.
The objects being discussed are carefully defined in each section and the contributions are organized according to the compactness of the binaries that are treated. Some treatments are of individual objects; others are more general.
The observational techniques that are used by the contributors to throw light on these objects include gravitational wave investigations, X-ray, radio, infrared, and optical astronomy; and the ways in which these objects are analyzed is also discussed. Among the specific objects reported is the Double Pulsar, highlighting what observations of this object tell us about fundamental physics.
The level of the book is appropriate for both professional astronomers in the field as well as people interested in other fields and dedicated amateur astronomers.