Philipp Podsiadlowski

Binaries with Compact Components: Theoretical and Observational Challenges

ArXiv astro-ph/0402024 (2004)

Authors:

Philipp Podsiadlowski, Eric Pfahl, Saul Rappaport

Abstract:

We report on recent progress in our theoretical understanding of X-ray binaries, which has largely been driven by new observations, and illustrate the interplay between theory and observations considering as examples intermediate-mass X-ray binaries, irradiation-driven evolution, ultraluminous X-ray sources and neutron stars with low-velocity kicks.

Exploring the Nature of Weak Chandra Sources Near the Galactic Centre

International Astronomical Union Colloquium Cambridge University Press (CUP) 194 (2004) 261-262

Authors:

RM Bandyopadhyay, KM Blundell, Ph Podsiadlowski, JCA Miller-Jones, QD Wang, WN Brandt, S Rappaport, E Pfahl

The massive binary companion star to the progenitor of supernova 1993J

Nature 427 (2004) 129-131

Authors:

P Podsiadlowski, Justyn R. Maund, Stephen J. Smartt, Rolf P. Kudritzki

The progenitors of sdB binaries: Confronting theory with observations

ASTROPHYS SPACE SCI 291:3 (2004) 291-298

Authors:

P Podsiadlowski, Z Han

Abstract:

We have re-examined the main binary evolution channels that produce sdB stars ( by stable and unstable mass transfer, the merging of two helium white dwarfs). We find that all three main channels are of comparable importance, but produce slightly different mass distributions and dominate at different times. We show how the short-period sdB binaries can be used to constrain the efficiency of common-envelope ejection and discuss various observational tests that will allow further testing and constrain the binary evolution parameters that go into binary population synthesis simulations.

The single degenerate channel for the progenitors of type Ia supernovae

ArXiv astro-ph/0309618 (2003)

Authors:

Zhanwen Han, Philipp Podsiadlowski

Abstract:

We have carried out a detailed study of one of the most popular evolutionary channels for the production of Type Ia supernova (SN Ia) progenitors, the semi-degenerate channel (CO+MS), where a carbon/oxygen (CO) white dwarf (WD) accretes matter from an unevolved or slightly evolved non-degenerate star until it reaches the Chandrasekhar mass limit. Employing Eggleton's stellar evolution code and adopting the prescription of Hachisu et al. (1999) for the accretion efficiency, we have carried out full binary evolution calculations for about 2300 close WD binary systems and mapped out the initial parameters in the orbital period -- secondary mass ($P$--$M_2$) plane (for a range of WD masses) which lead to a successful Type Ia supernova. We obtained accurate, analytical fitting formulae to describe this parameter range which can be used for binary population synthesis (BPS) studies. The contours in the $P$--$M_2$ plane differ from those obtained by Hachisu et al. (1999) for low-mass CO WDs, which are more common than massive CO WDs. We show that white dwarfs with a mass as low as $0.67M_\odot$ can accrete efficiently and reach the Chandrasekhar limit. We have implemented these results in a BPS study to obtain the birthrates for SNe Ia and the evolution of birthrates with time of SNe Ia for both a constant star formation rate and a single star burst. The birthrates are somewhat lower than (but comparable to) those inferred observationally.