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Recent Work on Beat Cepheids at Mount Stromlo Observatory

Published online by Cambridge University Press:  30 March 2016

S. L. Barrell ,
B. C. Cogan ,
D. J. Faulkner  and
R. R. Shobbrook
S. L. Barrell
Affiliation:
Mount Stromlo and Siding Spring Observatories, Australian National University, Canberra
B. C. Cogan
Affiliation:
Mount Stromlo and Siding Spring Observatories, Australian National University, Canberra
D. J. Faulkner
Affiliation:
Mount Stromlo and Siding Spring Observatories, Australian National University, Canberra
R. R. Shobbrook
Affiliation:
School of Physics, University of Sydney, Sydney

Extract

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Beat Cepheids continue to pose a number of unanswered questions concerning the behaviour of stars near the short-period end of the Cepheid instability strip; in particular, why is it that such a high proportion of stars with fundamental period ≤ 5 days exhibit simultaneous pulsation in both the fundamental and first-overtone radial modes, and why is it that these stars exhibit such a narrow range of period ratio (P1/P0 ≃ 0.71)? A programme of observation and Fourier analysis of beat Cepheids is presently being undertaken at Mount Stromlo and Siding Spring in an effort to understand these phenomena.

There is now evidence that, for the two best observed stars of this class - U TrA and TU Cas, both the period and the relative mode amplitudes are slowly changing with time. U TrA was observed in detail during the years 1953-59 by Oosterhoff (1957) and Jansen (1962), and a new series of 481 five colour observations of this star was obtained by Faulkner and Shobbrook (1979) in 1977. Using E = Σ(Amp × Freq)2 summed over all the Fourier terms for a given mode as a measure of the pulsational energy associated with that mode, we can use this 20 year timebase to calculate the change in relative mode energy. For U TrA the energy of the overtone is increasing (see Table I). Similarly we can compare the fundamental period derived for these 20 years with an earlier period estimate of Oosterhoff (1957) to obtain the rate of frequency change shown.

Type
Joint Discussion
Information
Highlights of Astronomy , Volume 5: Highlights of Astronomy. As presented at the XVIIth General Assembly of the IAU, 1979 , 1980 , pp. 483 - 485
Copyright
Copyright © Cambridge University Press 1980

References

Barrell, S.L., 1979. In preparation.Google Scholar
Cocito, G. & Masani, A., 1960. Mem.Soc.Astron.Ital., 31, 161.Google Scholar
Faulkner, D.J. & Cogan, B.C., 1979. In preparation.Google Scholar
Faulkner, D.J. & Shobbrook, R.R., 1979. Ap. J., In press.Google Scholar
Flower, P.J., 1978, Ap. J., 224 948.Google Scholar
Gieseking, F. & Radeke, H.W., 1978. Astron. Astrophys. Suppl., 183, 207.Google Scholar
Jansen, A.G., 1962. Bull.Astron.Inst.Netherlands, 16, 141.Google Scholar
Madore, B.F., Stobie, R.S. & van den Bergh, S., 1978. M.N.R.A.S., 183, 13.Google Scholar
Niva, G.D. & Schmidt, E.G., 1979. preprint.Google Scholar
Oosterhoff, P.Th., 1957. Bull.Astron.Inst.Netherlands, 13, 317.Google Scholar
Stobie, R.S., 1977. M.N.R.A.S., 180, 631.Google Scholar
Vasiljanovskaja, O.P., 1966. Bull.Inst.Astrof.Ak.W.Tadzh.SSR., 43, 21.Google Scholar
Worley, C.E. & Eggen, O.J., 1957. A. J., 62, 104.Google Scholar