posted on 2019-10-23, 15:02authored byJulian P. Osborne
Novae have been reported as transients for more than two thousand years. Their bright optical outbursts are the result of explosive nuclear burning of gas accreted from a binary companion onto a white dwarf. Novae containing a white dwarf close to the Chandrasekhar mass limit and accreting at a high rate are potentially the unknown progenitors of the type Ia supernovae used to measure the acceleration of the Universe. Swift X-ray observations have radically transformed our view of novae by providing dense monitoring throughout the outburst, revealing new phenomena in the super-soft X-rays from the still-burning white dwarf such as early extreme variability and half- to one-minute timescale quasi-periodic oscillations. The distinct evolution of this emission from the harder X-ray emission due to ejecta shocks has been clearly delineated. Soft X-ray observations allow the mass of the white dwarf, the mass burned and the mass ejected to be estimated. In combination with observations at other wavelengths, including the high spectral resolution observations of the large X-ray observatories, high resolution optical and radio imaging, radio monitoring, optical spectroscopy, and the detection of GeV gamma-ray emission from recent novae, models of the explosion have been tested and developed. I review nine novae for which Swift has made a significant impact; these have shown the signature of the components in the interacting binary system in addition to the white dwarf: the re-formed accretion disk, the companion star and its stellar wind.
Funding
The success of Swift is due to the small, dedicated
instrument, mission operations and data analysis
software teams in the USA, the UK and Italy,
following the highly effective leadership of the
Principal Investigator, Neil Gehrels; it has been my
pleasure to be a part of this, and to acknowledge
this great team. I also acknowledge the skill and
achievement of the University of Leicester XRT
camera hardware team, led pre-launch by Alan
Wells, from which the current Leicester team has
evolved. The work described here has been mostly
undertaken by the Swift nova-CV group, an open
and loose collaboration that I have enjoyed coordinating with the significant help of Kim Page:
http://www.swift.ac.uk/nova-cv The Swift project
at the University of Leicester is funded by the UK
Space Agency.
History
Citation
Journal of High Energy Astrophysics, 2015, 7, pp. 117-125 (9)
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Physics and Astronomy