Non-Periodic Phenomena in Variable Stars
IAU Colloquium, Budapest, 1968
FLARE STARS NEAR NGC 7023
L. V. MIRZOYAN and E. S. PARSAMIAN
Byurakan Astrophysical Observatory, Armenia, USSR
The distribution of flare stars in T-associations can give some definite
information about the early stages of stellar evolution. In order to determine
this distribution the small T-association near NGC 7023 has been selected. Being
very compact and comparatively close to us it is suitable for the mentioned
purpose. The photographic observations of the NGC 7023 region began in 1962.
The 40" Schmidt telescope of the Byurakan Astrophysical Observatory
of the Academy of Sciences of Armenian SSR was used. 92 plates with 479
five-minutes serial exposures embracing an effective observational time of
40h were obtained. The limiting magnitude on our plates is 18.5m, consequently
flare stars with absolute magnitude brighter than +11m (for the distance
of the T-association equal to 280 pc, Weston 1953) can be detected on these
plates. Nine flare stars (Mirzoyan et al. 1968 a, b), two of which flared twice
during our exposures, have been found. Another possible flare star in this
region has been announced by Rosino and Romano (1962). Thus, the number
of known flare stars in this region is equal to 10.
This number can be used for a rough estimation of the total number
of flare stars in this region brighter than M ~ + 11m.
Assuming, that the probability P_k of flare appearance obeys the Poisson's
law:
P_K = e^-nu*t (nu*t)^K/ K!
where t denotes the duration of the observations, nu the frequency of flares,
K the number of flares during t, respectively, and using for the mathematical
expectation of the number of stars flared K times, the expression
N_K=NP_K,
one can calculate the number N of all probable flare stars in this region. With
our small statistics (N_l = 8, N_2 = 2) we obtain N = 27. From this data
also follows that the mean time interval between flares is 3.3d. It is difficult
to discover photographically flares with amplitudes less than 0.5m. Therefore,
these numbers correspond to flare stars with amplitudes larger than 0.5m.
Since the duration of the flare-maximum can be shorter than 5 min, i.e.,
shorter than our exposure time and the starting point of the exposures may
correspond to different moments of the flares, the estimated amplitudes are
in fact always less than the real ones. Therefore, the real number of flares
with amplitudes exceeding 0.5m must be larger and the mean time interval
between flares correspondingly smaller than estimated. Naturally, our
calculations refer only to stars brighter than M = +11. The number of
corresponding stars in the Pleiades (r = 126 pc), is equal to 20 (Haro 1968).
The total duration of the corresponding observations in Pleiades is about 189^h.
The calculations similar to that brought above give N = 112 for the total number
of flare stars in the Pleiades. Therefore, assuming that the luminosity function
of flare stars in the region of NGC 7023 is close to that of the Pleiades, one
can conclude that the number of all flare stars in the region of NGC 7023
differs not much from the corresponding number in the Pleiades.
Fig. 1
Of particular interest is the distribution of the known flare stars in the
region of NGC 7023 presented in Fig. 1. It shows that eight flare stars out
of ten are situated far from the centre of the T-association, probably farther
than the limits of the association showed by the dotted circle having a radius
of 1 deg (Kholopov, 1959). The remaining two stars have probably come to the
central part of the cluster through the effect of projection, in reality they
may be far from the centre in space. Thus, it may be suggested that the flare
stars surround the T-association. It must be noted, we suppose, that all
detected flare stars in the region of NGC 7023 are in a distance equal to the
distance of the T-association. The opposite assumption, i.e. that they are
field stars, is less probable, because of the very high frequency of flares of
field stars needed in this case.
If one assumes that all of them have been originated in the central
region of the association, then the distribution of flare stars confirms Haro's
(1965) hypothesis, according to which the flare stage of a star follows the
T Tauri stage.
On the other hand if we suppose Haro's hypothesis to be correct, the
observed distribution of flare stars around the T-association NGC 7023 can be
interpreted as a confirmation of the expansion of this association. However,
our statistical sample is not rich enough for a final conclusion.
The authors thank to Prof. Ambarzumian for valuable advices.
REFERENCES
Haro, G., Chavira, E., 1965, Vistas in Astronomy, vol. 8, 89.
Haro, G., 1968, Stars and Stellar Systems, vol. VII. 147.
Kholopov, P. P., 1959, Astron. Zu. 36, 295.
Mirzoyan, L. V., Parsamian, E. S., Chavushian, O. S., 1968a, Soobshch. Byurakan Obs.
39, 3.
Mirzoyan, L. V., Parsamian, E. S., Kalloglian, N. L. 1968b, unpublished.
Rosin, L., Romano, G., 1962, Asiago Contr. N. 127.
Weston, E. B. 1953, Astr. J. 58, 48.
DISCUSSION
Rosino: I should like to know whether flares have been observed in known
nebular variables of NGC 7023 or whether the flares are usually
observed in stars which are not nebular variables.
Parsamian: No one of these flare stars coincide with known nebular variable
stars in this region.