SIMBAD references

2004MNRAS.348..469A - Mon. Not. R. Astron. Soc., 348, 469-481 (2004/February-3)

On the origin of red giant depletion through low-velocity collisions.

ADAMS T., DAVIES M.B. and SILLS A.

Abstract (from CDS):

We investigate a means of explaining the apparent paucity of red giant stars within post-core-collapse globular clusters. We propose that collisions between the red giants and binary systems can lead to the destruction of some proportion of the red giant population, by either knocking out the core of the red giant or by forming a common envelope system which will lead to the dissipation of the red giant envelope. Treating the red giant as two point masses, one for the core and another for the envelope (with an appropriate force law to take account of the distribution of mass), and the components of the binary system also treated as point masses, we utilize a four-body code to calculate the time-scales on which the collisions will occur. We then perform a series of smooth particle hydrodynamics runs to examine the details of mass transfer within the system. In addition, we show that collisions between single stars and red giants lead to the formation of a common envelope system which will destroy the red giant star. We find that low-velocity collision between binary systems and red giants can lead to the destruction of up to 13 per cent of the red giant population. This could help to explain the colour gradients observed in PCC globular clusters. We also find that there is the possibility that binary systems formed through both sorts of collision could eventually come into contact perhaps producing a population of cataclysmic variables.

Abstract Copyright: 2004 RAS

Journal keyword(s): stellar dynamics - celestial mechanics - binaries: general - globular clusters: general

Simbad objects: 18

goto Full paper

goto View the reference in ADS

To bookmark this query, right click on this link: simbad:2004MNRAS.348..469A and select 'bookmark this link' or equivalent in the popup menu


2021.06.19-08:41:54

© Université de Strasbourg/CNRS

    • Contact