32 research outputs found
Physical properties of seven binary and higher-order multiple OB systems
Analyses of multi-epoch, high-resolution (~ 50000) optical spectra of seven
early-type systems provided various important new insights with respect to
their multiplicity. First determinations of orbital periods were made for HD
92206C (2.022 d), HD 112244 (27.665 d), HD 164438 (10.25 d), HD 123056A (~ 1314
d) and HD 123056B (< 2 d); the orbital period of HD 318015 could be improved
(23.445975 d). Concerning multiplicity, a third component was discovered for HD
92206C by means of He I line profiles. For HD 93146A, which was hitherto
assumed to be SB1, lines of a secondary component could be discerned. HD 123056
turns out to be a multiple system consisting of a high-mass component A (~
O8.5) displaying a broad He II 5411 A feature with variable radial velocity,
and of an inner pair B (~ B0) with double He I lines. The binary HD 164816 was
revisited and some of its system parameters were improved. In particular, we
determined its systemic velocity to be -7 km/s, which coincides with the radial
velocity of the cluster NGC 6530. This fact, together with its distance,
suggests the cluster membership of HD 164816. The OB system HD 318015 (V1082
Sco) belongs to the rare class of eclipsing binaries with a supergiant primary
(B0.5/0.7). Our combined orbital and light-curve analysis suggests that the
secondary resembles an O9.5III star. Our results for a limited sample
corroborate the findings that many O stars are actually massive multiple
systems.Comment: 16 pages, 16 figures, to appear in Astronomy and Astrophysic
Hydrodynamical and radiative modeling of temporal H{\alpha} emission V/R variations caused by a discontinuous mass transfer in binaries
H{\alpha} emission V/R variations caused by a discontinous mass transfer in
interacting binaries with a rapidly rotating accreting star are modelled
qualititatively for the first time. The program ZEUS-MP was used for a
non-linear 3-D hydrodynamical modeling of a development of a blob of gaseous
material injected into an orbit around a star. It resulted in the formation of
an elongated disk with a slow prograde revolution. The LTE radiative transfer
program SHELLSPEC was used to calculate the H{\alpha} profiles originating in
the disk for several phases of its revolution. The profiles have the form of a
double emission and exhibit V/R and radial velocity variations. However, these
variations should be a temporal phenomenon since imposing a viscosity in given
model would lead to a circularization of the disk and fading-out of given
variations.Comment: accepted for a publication in Astronomical Journa
Searching for transit timing variations in transiting exoplanet systems
Searching for transit timing variations in the known transiting exoplanet
systems can reveal the presence of other bodies in the system. Here we report
such searches for two transiting exoplanet systems, TrES-1 and WASP-2. Their
new transits were observed with the 4.2m William Herschel Telescope located on
La Palma, Spain. In a continuing programme, three consecutive transits were
observed for TrES-1, and one for WASP-2 during September 2007. We used the
Markov Chain Monte Carlo simulations to derive transit times and their
uncertainties. The resulting transit times are consistent with the most recent
ephemerides and no conclusive proof of additional bodies in either system was
found.Comment: To appear in the Proceedings of the 253rd IAU Symposium: "Transiting
Planets", May 2008, Cambridge, MA. 4 pages, 3 figures, 1 tabl
Interferometric observations of the multiple stellar system delta Velorum
delta Velorum is a nearby (24pc) triple stellar system, containing a close,
eclipsing binary (Aa, Ab) discovered in 2000. Multiple systems provide an
opportunity to determine the set of fundamental parameters (mass, luminosity,
size and chemical composition) of coeval stars. These parameters can be
obtained with particular precision in the case of eclipsing binaries; for delta
Velorum's components (Aa, Ab) this potential has however not yet been
exploited. We have analyzed interferometric observations of the close binary
(Aa, Ab), obtained with the VINCI instrument and two VLTI siderostats. The
measurements, which resolve the two components for the first time, are fitted
onto the simple model of two uniformly bright, spherical stars. The
observations suggest that Aa and Ab have larger diameters than expected if they
were on the main sequence, and that they are, thus, in a later evolutionary
state.Comment: 6 pages, Research Note accepted for publication in A&
Call to adopt a nominal set of astrophysical parameters and constants to improve the accuracy of fundamental physical properties of stars
The increasing precision of astronomical observations of stars and stellar
systems is gradually getting to a level where the use of slightly different
values of the solar mass, radius and luminosity, as well as different values of
fundamental physical constants, can lead to measurable systematic differences
in the determination of basic physical properties. An equivalent issue with an
inconsistent value of the speed of light was resolved by adopting a nominal
value that is constant and has no error associated with it. Analogously, we
suggest that the systematic error in stellar parameters may be eliminated by:
(1) replacing the solar radius Rsun and luminosity Lsun by the nominal values
that are by definition exact and expressed in SI units: 1 RnomSun = 6.95508 x
10^8 m and 1 LnomSun = 3.846 x 10^{26} W; (2) computing stellar masses in terms
of Msun by noting that the measurement error of the product G.Msun is 5 orders
of magnitude smaller than the error in G; (3) computing stellar masses and
temperatures in SI units by using the derived values Msun(2010) = 1.988547 x
10^{30} kg and Tsun(2010) = 5779.57 K; and (4) clearly stating the reference
for the values of the fundamental physical constants used. We discuss the need
and demonstrate the advantages of such a paradigm shift.Comment: 6 pages, 3 table
NOMINAL VALUES FOR SELECTED SOLAR AND PLANETARY QUANTITIES: IAU 2015 RESOLUTION B3
In this brief communication we provide the rationale for and the outcome of the International Astronomical Union (IAU) resolution vote at the XXIXth General Assembly in Honolulu, Hawaii, in 2015, on recommended nominal conversion constants for selected solar and planetary properties. The problem addressed by the resolution is a lack of established conversion constants between solar and planetary values and SI units: a missing standard has caused a proliferation of solar values (e.g., solar radius, solar irradiance, solar luminosity, solar effective temperature, and solar mass parameter) in the literature, with cited solar values typically based on best estimates at the time of paper writing. As precision of observations increases, a set of consistent values becomes increasingly important. To address this, an IAU Working Group on Nominal Units for Stellar and Planetary Astronomy formed in 2011, uniting experts from the solar, stellar, planetary, exoplanetary, and fundamental astronomy, as well as from general standards fields to converge on optimal values for nominal conversion constants. The effort resulted in the IAU 2015 Resolution B3, passed at the IAU General Assembly by a large majority. The resolution recommends the use of nominal solar and planetary values, which are by definition exact and are expressed in SI units. These nominal
values should be understood as conversion factors only, not as the true solar/planetary properties or current best estimates. Authors and journal editors are urged to join in using the standard values set forth by this resolution in
future work and publications to help minimize further confusion
Hot emission-line stars after 134 years of study. A personal view of current problems
A brief review of current problems in the research of hot emission-line stars is presented. Special attention is paid to problems of reliable determination of basic physical properties of underlying stars and to possible role of duplicity in the whole phenomenon