Philipp Podsiadlowski

Simulations of RS Oph and the CSM in Type Ia Supernovae

Proceedings of the International Astronomical Union Cambridge University Press (CUP) 9:S296 (2013) 382-383

Authors:

Richard A Booth, Shazrene Mohamed, Philipp Podsiadlowski

The Link Between RS Ophiuchi and Type Ia Supernovae

18TH EUROPEAN WHITE DWARF WORKSHOP 469 (2013) 323-+

Authors:

S Mohamed, R Booth, Ph Podsiadlowski

A High-Resolution Spectroscopic Search for the Remaining Donor for Tycho's Supernova

ArXiv 1210.2713 (2012)

Authors:

Wolfgang E Kerzendorf, David Yong, Brian P Schmidt, Joshua D Simon, C Simon Jeffery, Jay Anderson, Philipp Podsiadlowski, Avishay Gal-Yam, Jeffrey M Silverman, Alexei V Filippenko, Ken'ichi Nomoto, Simon J Murphy, Michael S Bessell, Kim A Venn, Ryan J Foley

Abstract:

In this paper, we report on our analysis using Hubble Space Telescope astrometry and Keck-I HIRES spectroscopy of the central six stars of Tycho's supernova remnant (SN 1572). With these data, we measured the proper motions, radial velocities, rotational velocities, and chemical abundances of these objects. Regarding the chemical abundances, we do not confirm the unusu- ally high [Ni/Fe] ratio previously reported for Tycho-G. Rather, we find that for all metrics in all stars, none exhibit the characteristics expected from traditional SN Ia single-degenerate-scenario calculations. The only possible exception is Tycho-B, a rare, metal-poor A-type star; however, we are unable to find a suitable scenario for it. Thus, we suggest that SN 1572 cannot be explained by the standard single-degenerate model.

Common Envelope Evolution: Where we stand and how we can move forward

ArXiv 1209.4302 (2012)

Authors:

N Ivanova, S Justham, X Chen, O De Marco, CL Fryer, E Gaburov, H Ge, E Glebbeek, Z Han, X-D Li, G Lu, T Marsh, Ph Podsiadlowski, A Potter, N Soker, R Taam, TM Tauris, EPJ van den Heuvel, RF Webbink

Abstract:

This work aims to present our current best physical understanding of common-envelope evolution (CEE). We highlight areas of consensus and disagreement, and stress ideas which should point the way forward for progress in this important but long-standing and largely unconquered problem. Unusually for CEE-related work, we mostly try to avoid relying on results from population synthesis or observations, in order to avoid potentially being misled by previous misunderstandings. As far as possible we debate all the relevant issues starting from physics alone, all the way from the evolution of the binary system immediately before CEE begins to the processes which might occur just after the ejection of the envelope. In particular, we include extensive discussion about the energy sources and sinks operating in CEE, and hence examine the foundations of the standard energy formalism. Special attention is also given to comparing the results of hydrodynamic simulations from different groups and to discussing the potential effect of initial conditions on the differences in the outcomes. We compare current numerical techniques for the problem of CEE and also whether more appropriate tools could and should be produced (including new formulations of computational hydrodynamics, and attempts to include 3D processes within 1D codes). Finally we explore new ways to link CEE with observations. We compare previous simulations of CEE to the recent outburst from V1309 Sco, and discuss to what extent post-common-envelope binaries and nebulae can provide information, e.g. from binary eccentricities, which is not currently being fully exploited.

Hunting for the progenitor of SN 1006: High resolution spectroscopic search with the FLAMES instrument

ArXiv 1207.4481 (2012)

Authors:

Wolfgang E Kerzendorf, Brian P Schmidt, John B Laird, Philipp Podsiadlowski, Michael S Bessell

Abstract:

Type Ia supernovae play a significant role in the evolution of the Universe and have a wide range of applications. It is widely believed that these events are the thermonuclear explosions of carbon-oxygen white dwarfs close to the Chandrasekhar mass (1.38 M\odot). However, CO white dwarfs are born with masses much below the Chandrasekhar limit and thus require mass accretion to become Type Ia supernovae. There are two main scenarios for accretion. First, the merger of two white dwarfs and, second, a stable mass accretion from a companion star. According to predictions, this companion star (also referred to as donor star) survives the explosion and thus should be visible in the center of Type Ia remnants. In this paper we scrutinize the central stars (79 in total) of the SN 1006 remnant to search for the surviving donor star as predicted by this scenario. We find no star consistent with the traditional accretion scenario in SN1006.