Abstract:
Aims. It is important to know the binary mass-ratio distribution to better understand the evolution of stars in binary systems and to constrain their formation. However, in most cases, that is, for single-lined spectroscopic binaries, the mass ratio cannot be measured directly, but can only be derived as the convolution of a function that depends on the mass ratio and on the unknown inclination angle of the orbit on the plane of the sky. Methods. We extend our previous method for deconvolving this inverse problem by obtaining the cumulative distribution function (CDF) for the mass-ratio distribution as an integral. Results. After a suitable transformation of variables, this problem becomes the same as the problem of rotational velocities vsini, allowing a close analytic formulation for the CDF. We here apply our method to two real datasets: a sample of Am star binary systems, and a sample of massive spectroscopic binaries in the Cyg OB2 association. Conclusions. We are able to reproduce previous results for the sample of Am stars. In addition, the mass-ratio distribution of massive stars shows an excess of systems with a low mass ratio, in contrast to what was claimed elsewhere. Our method proves to be very reliable and deconvolves the distribution from a sample in one single step. © 2014 ESO.
Registro:
Documento: |
Artículo
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Título: | A method to deconvolve mass ratio distribution of binary stars |
Autor: | Curé, M.; Rial, D.F.; Cassetti, J.; Christen, A.; Boffin, H.M.J. |
Filiación: | Instituto de Física y Astronomía, Universidad de Valparaíso, Chile Departamento de Matemáticas, Facultad de Ciencias Exactas y Naturales, Universidad de Buenos Aires, Argentina Universidad Nacional de General Sarmiento, Buenos Aires, Argentina Instituto de Estadística, Pontificia Universidad Católica de Valparaíso, Chile ESO, Vitacura, Santiago, Chile
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Palabras clave: | Binaries: general; Methods: analytical; Methods: data analysis; Methods: numerical; Methods: statistical; Stars: fundamental parameters; Distribution functions; Inverse problems; Stars; Systems (metallurgical); Binaries: general; Methods: numericals; Methods:analytical; Methods:data analysis; Methods:statistical; Stars:fundamental parameters; Numerical methods |
Año: | 2015
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Volumen: | 573
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DOI: |
http://dx.doi.org/10.1051/0004-6361/201424531 |
Título revista: | Astronomy and Astrophysics
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Título revista abreviado: | Astron. Astrophys.
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ISSN: | 00046361
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CODEN: | AAEJA
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Registro: | https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00046361_v573_n_p_Cure |
Referencias:
- Bate, M.R., (2012) MNRAS, 419, p. 3115
- Bi, H., Boerner, G., (1994) A&AS, 108, p. 409
- Boffin, H.M.J., (2010) A&A, 524, p. 14
- Boffin, H.M.J., (2012) Proc. of the Workshop Orbital Couples: Pas de Deux in the Solar System and the Milky Way, Held at the Observatoire de Paris, p. 41. , eds. F. Arenou, & D. Hestroffer
- Boffin, H.M.J., Paulus, G., Cerf, N., (1992) Binaries As Tracers of Star Formation, p. 26
- Boffin, H.M.J., Cerf, N., Paulus, G., (1993) A&A, 271, p. 125
- Brown, R.A., (2011) ApJ, 733, p. 68
- Cerf, N., Boffin, H.M.J., (1994) Inverse Problems, 10, p. 533
- Chandrasekhar, S., Münch, G., (1950) ApJ, 111, p. 142
- Clarke, C.J., (2007) Binary Stars As Critical Tools & Tests in Contemporary Astrophysics, 240, p. 337. , eds. W. I. Hartkopf, E. F. Guinan, & P. Harmanec (Cambridge University Press), Proc. IAU Symp
- Curé, M., Rial, D.F., Christen, A., Cassetti, J., (2014) A&A, 565, p. 85. , (Paper I)
- Efrom, B., Tibshirani, R.J., (1993) An Introduction to the Bootstrap, , (London: Chapman and Hall)
- Halbwachs, J.L., (1987) A&A, 183, p. 234
- Halbwachs, J.L., Mayor, M., Udry, S., Arenou, F., (2003) A&A, 397, p. 159
- Heacox, W.D., (2005) AJ, 109, p. 2670
- Knowles, I., Remka, R.J., Variational and topological methods: Theory, applications, numerical simulations, and open problems (2014) Electron. J. Diff. Eqns., Conference, 21, p. 235
- Kouwenhoven, M.B.N., Brown, A.G.A., Goodwin, S.P., (2009) A&A, 493, p. 979
- Kobulnicky, H.A., Kiminki, D.C., Lundquist, M.J., (2014) ApJS, 213, p. 34
- Lucy, L.B., (1974) AJ, 79, p. 745
- Lucy, L.B., (1994) Rev. Mod. Astron., 7, p. 31
- Mazeh, T., Goldberg, D., (1992) ApJ, 394, p. 592
- Press, W.H., Teukolsky, S.A., Vetterling, W.T., (1993) The Observatory, 113, p. 214
- Smalley, B., Southworth, J., Pintado, O.I., (2014) A&A, 564, p. 69
- Tikhonov, A.N., Arsenin, V.Y., (1977) Solution of Ill-posed Problems, , (Washington: Winston & Sons)
- Tikhonov, A.N., Goncharsky, A.V., Stepanov, V.V., (1995) Numerical Methods for the Solution of Ill-Posed Problems, , (Kluwer Academic Publishers)
- Watkins, S.J., Boffin, H.M.J., Francis, N., Whitworth, A.P., (1998) Star Formation with the Infrared Space Observatory, ASP Conf. Ser., 132, p. 430
Citas:
---------- APA ----------
Curé, M., Rial, D.F., Cassetti, J., Christen, A. & Boffin, H.M.J.
(2015)
. A method to deconvolve mass ratio distribution of binary stars. Astronomy and Astrophysics, 573.
http://dx.doi.org/10.1051/0004-6361/201424531---------- CHICAGO ----------
Curé, M., Rial, D.F., Cassetti, J., Christen, A., Boffin, H.M.J.
"A method to deconvolve mass ratio distribution of binary stars"
. Astronomy and Astrophysics 573
(2015).
http://dx.doi.org/10.1051/0004-6361/201424531---------- MLA ----------
Curé, M., Rial, D.F., Cassetti, J., Christen, A., Boffin, H.M.J.
"A method to deconvolve mass ratio distribution of binary stars"
. Astronomy and Astrophysics, vol. 573, 2015.
http://dx.doi.org/10.1051/0004-6361/201424531---------- VANCOUVER ----------
Curé, M., Rial, D.F., Cassetti, J., Christen, A., Boffin, H.M.J. A method to deconvolve mass ratio distribution of binary stars. Astron. Astrophys. 2015;573.
http://dx.doi.org/10.1051/0004-6361/201424531