Philipp Podsiadlowski

The quiescent light curve and the evolutionary state of GRO J1655-40

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY 331:2 (2002) 351-360

Authors:

ME Beer, P Podsiadlowski

The slow merger of massive stars: Merger types and post-merger evolution

ASTR SOC P 279 (2002) 245-251

Authors:

N Ivanova, P Podsiadlowski

Abstract:

We study the slow merger of two massive stars inside a common envelope: The initial close binary system consists of a massive red supergiant and a main-sequence companion of a few solar, masses. The merger product is a massive supergiant with an interior structure (core mass and composition profile) which is significantly different from that of a single supergiant that has evolved in isolation: Using a parameterized approach for the stream-core interaction, we modelled the merger phase and have identified three qualitatively different merger types: quiet, moderate and explosive mergers, where the differences are caused by the different response of the He burning shell. In the last two scenarios, the post-merger He abundance in the envelope is found to be substantially increased, but significant s-processing is mainly expected in the case of an explosive merger scenario. The subsequent evolution of the merger product up to the supernova stage is also discussed.

Massive Star Mergers: Induced Mixing and Nucleosynthesis

ArXiv astro-ph/0112039 (2001)

Authors:

N Ivanova, Ph Podsiadlowski

Abstract:

We study the nucleosynthesis and the induced mixing during the merging of massive stars inside a common envelope. The systems of interest are close binaries, initially consisting of a massive red supergiant and a main-sequence companion of a few solar masses. We apply parameterized results based on hydrodynamical simulations to model the stream-core interaction and the response of the star in a standard stellar-evolution code. Preliminary results are presented illustrating the possibility of unusual nucleosynthesis and post-merging dredge-up which can cause composition anomalies in the supergiant's envelope.

A New Class of High-Mass X-ray Binaries: Implications for Core Collapse and Neutron-Star Recoil

ArXiv astro-ph/0109521 (2001)

Authors:

E Pfahl, S Rappaport, Ph Podsiadlowski, H Spruit

Abstract:

We investigate an interesting new class of high-mass X-ray binaries (HMXBs) with long orbital periods (P_orb > 30 days) and low eccentricities (e <~ 0.2). The orbital parameters suggest that the neutron stars in these systems did not receive a large impulse, or ``kick,'' at the time of formation. We develop a self-consistent phenomenological picture wherein the neutron stars born in the observed wide HMXBs receive only a small kick (<~ 50 km/s), while neutron stars born in isolation, in the majority of low-mass X-ray binaries, or in many of the well-known HMXBs with P_orb <~ 30 days receive the conventional large kicks, with a mean speed of ~ 300 km/s. We propose that the magnitude of the natal kick to a neutron star born in a binary system depends on the rotation rate of the pre-collapse core. We further suggest that the rotation rate of the core is a strong, well-defined function of the evolutionary path of the progenitor star.

Hydrodynamical Simulations of the Stream-Core Interaction in the Slow Merger of Massive Stars

ArXiv astro-ph/0109524 (2001)

Authors:

N Ivanova, Ph Podsiadlowski, H Spruit

Abstract:

We present detailed simulations of the interaction of a stream emanating from a mass-losing secondary with the core of a massive supergiant in the slow merger of the two stars inside a common envelope. The dynamics of the stream can be divided into a ballistic phase, starting at the L_1 point, and a hydrodynamical phase where the stream interacts strongly with the core. Considering the merger of a 1 and 5Msun star with a 20Msun evolved supergiant, we present two-dimensional hydrodynamical simulations using the PROMETHEUS code to demonstrate how the penetration depth and post-impact conditions depend on the initial properties of stream material (e.g. entropy, angular momentum, stream width) and the properties of the core (e.g. density structure and rotation rate). Using these results, we present a fitting formula for the entropy generated in the stream--core interaction and a recipe for the determination of the penetration depth based on a modified Bernoulli integral.