Document 
- Same authors
-
Related articles
- Recommend this article
- Download citation
- Alert me when this article is cited
- Alert me when this article is corrected
BibSonomy
CiteUlike
Connotea
Del.icio.us
Digg
Facebook
|
A&A 500, L21-L24 (2009)
DOI: 10.1051/0004-6361/200911952
Letter
Mode lifetimes of stellar oscillations
Implications for asteroseismology
W. J. Chaplin1, G. Houdek2, 3, C. Karoff1, Y. Elsworth1, and R. New41 School of Physics and Astronomy, University of Birmingham, Edgbaston, Birmingham B15 2TT, UK
e-mail: w.j.chaplin@bham.ac.uk
2 Institut für Astronomie, Universität Wien, Türkenschanzstraße 17, 1180 Vienna, Austria
3 Institute of Astronomy, University of Cambridge, Cambridge CB3 0HA, UK
4 Faculty of Arts, Computing, Engineering and Sciences, Sheffield Hallam University, Sheffield S1 1WB, UK
Received 25 February 2009 / Accepted 7 May 2009
Abstract
Context. Successful inference from asteroseismology relies on at
least two factors: that the oscillations in the stars have
amplitudes large enough to be clearly observable, and that the
oscillations themselves be stable enough to enable precise
measurements of mode frequencies and other parameters. Solar-like
p modes are damped by convection, and hence the stability of the
modes depends on the lifetime.
Aims. We seek a simple scaling relation
between the mean lifetime of the most prominent solar-like p modes
in stars, and the fundamental stellar parameters.
Methods. We base our
search for a relation on the use of stellar equilibrium and
pulsation computations of a grid of stellar models, and the first
asteroseismic results on lifetimes of main-sequence, sub-giant and
red-giant stars.
Results. We find that the mean lifetimes of all three
classes of solar-like stars scale like
(where
is the effective temperature). When this relation is
combined with the well-known scaling relation of Kjeldsen &
Bedding for mode amplitudes observed in narrow-band intensity
observations, we obtain the unexpected result that the height (the
maximum power spectral density) of mode peaks in the frequency
power spectrum scales as g-2 (where g is the surface
gravity). As it is the mode height (and not the amplitude) that
fixes the S/N at which the modes can be measured, and as g
changes only slowly along the main sequence, this suggests that
stars cooler than the Sun might be as good targets for
asteroseismology as their hotter counterparts. When observations
are instead made in Doppler velocity, our results imply that mode
height does increase with increasing effective temperature.
Key words: convection -- stars: oscillations -- methods: data analysis
© ESO 2009
| What is OpenURL? |
