168 research outputs found
The structure and kinematics of the the Galaxy thin gaseous disc outside the solar orbit
The rotation curve of the Galaxy is generally thought to be flat. However,
using radial velocities from interstellar molecular clouds, which is common in
rotation curve determination, seems to be incorrect and may lead to incorrectly
inferring that the rotation curve is flat indeed. Tests basing on photometric
and spectral observations of bright stars may be misleading. The rotation
tracers (OB stars) are affected by motions around local gravity centers and
pulsation effects seen in such early type objects. To get rid of the latter a
lot of observing work must be involved. We introduce a method of studying the
kinematics of the thin disc of our Galaxy outside the solar orbit in a way that
avoids these problems. We propose a test based on observations of interstellar
CaII H and K lines that determines both radial velocities and distances. We
implemented the test using stellar spectra of thin disc stars at galactic
longitudes of 135{\degr} and 180{\degr}. Using this method, we constructed the
rotation curve of the thin disc of the Galaxy. The test leads to the obvious
conclusion that the rotation curve of the thin gaseous galactic disk,
represented by the CaII lines, is Keplerian outside the solar orbit rather than
flat.Comment: 33 pages, 18 figures, accepted for publication in Publications of the
Astronomical Society of the Pacific, 2015. February
The chemical composition of a mild barium star HD202109
We present the result of chemical abundances of a mild barium star HD202109
(zeta Cyg) determined from the analysis of spectrum obtained by using a 2-m
telescope at the Peak Terskol Observatory and a high-resolution spectrometer
with R=80,000, signal to noise ratio >100. We also present the atmospheric
parameters of the star determined by using various methods including iron-line
abundance analysis. For line identifications, we use whole-range synthetic
spectra computed by using the Kurucz database and the latest lists of spectral
lines. Among the determined abundances of 51 elements, those of P, S, K, Cu,
Zn, Ge, Rb, Sr, Nb, Mo, Ru, Rh, Pd, In, Sm, Gd, Tb, Dy, Er, Tm, Hf, Os, Ir, Pt,
Tl, and Pb have not been previously known. Under the assumption that the
overabundance pattern of Ba stars is due to wind-accretion process, adding
information of more element abundances enables one to show that the heavy
element overabundances of HD202109 can be explained with the wind accretion
scenario model.Comment: 10 pages, Accepted by Astronomy and Astrophysic
A novel and sensitive method for measuring very weak magnetic fields of DA white dwarfs: A search for a magnetic field at the 250 G level in 40 Eri B
Searches for magnetic fields in white dwarfs have clarified both the
frequency of occurrence and the global structure of the fields found down to
field strengths of the order of 500 kG. Below this level, the situation is
still very unclear. We are studying the weakest fields found in white dwarfs to
determine the frequency of such fields and their structure. We describe a very
sensitive new method of measuring such fields in DA (H-rich) white dwarfs, and
search for a field in the brightest such star, 40 Eri B. Our new method makes
use of the strongly enhanced polarisation signal in the sharp core of Halpha.
We find that with one-hour integrations with the high-resolution
spectropolarimeter ESPaDOnS on the 3.6-m CFHT, we can reach a standard error fo
the longitudinal field of about 85 G, the smallest error ever achieved for any
white dwarf. Nevertheless, we do not detect a magnetic field in this star.
Observations with ISIS at the WHT, and the Main Stellar Spectrograph at the
SAO, support the absence of a field at somewhat lower precision. The new method
is very efficient; it is shown that for suitable DA stars the integration time,
with ESPaDOnS on a 3.6-m telescope, to reach a 500 G standard error on a white
dwarf of V = 12.5, is about half an hour, about the same as the time required
on an ESO 8-m telescope with FORS using conventional low-resolution
spectropolarimetry.Comment: Accepted by Astronomy & Astrophysics on 20/06/201
Detection of vibronic bands of C in a translucent cloud towards HD 169454
We report the detection of eight vibronic bands of C, seven of which have
been hitherto unobserved in astrophysical objects, in the translucent cloud
towards HD~169454. Four of these bands are also found towards two additional
objects: HD~73882 and HD~154368. Very high signal-to-noise ratio (1000
and higher) and high resolving power () UVES-VLT spectra (Paranal,
Chile) allow for detecting novel spectral features of C, even revealing
weak perturbed features in the strongest bands. The work presented here
provides the most complete spectroscopic survey of the so far largest carbon
chain detected in translucent interstellar clouds. High-quality laboratory
spectra of C are measured using cavity ring-down absorption spectroscopy in
a supersonically expanding hydrocarbon plasma, to support the analysis of the
identified bands towards HD~169454. A column density of N(C) = cm is inferred and the excitation of the molecule
exhibits two temperature components; K for the low-
states and K for the high- tail. The rotational
excitation of C is reasonably well explained by models involving a
mechanism including inelastic collisions, formation and destruction of the
molecule, and radiative pumping in the far-infrared. These models yield gas
kinetic temperatures comparable to those found for . The assignment of
spectral features in the UV-blue range 3793-4054 \AA\ may be of relevance for
future studies aiming at unravelling spectra to identify interstellar molecules
associated with the diffuse interstellar bands (DIBs).Comment: 15 pages, 13 figures, submitted to MNRA
Centrosymmetric molecules as possible carriers of diffuse interstellar bands
In this paper, we present new data with interstellar C2 (Phillips bands A-X),
from observations made with the Ultraviolet-Visual Echelle Spectrograph of the
European Southern Observatory. We have determined the interstellar column
densities and excitation temperatures of C2 for nine Galactic lines. For seven
of these, C2 has never been observed before, so in this case the still small
sample of interstellar clouds (26 lines of sight), where a detailed analysis of
C2 excitation has been made, has increased significantly. This paper is a
continuation of previous works where interstellar molecules (C2 and diffuse
interstellar bands) have been analysed. Because the sample of interstellar
clouds with C2 has increased, we can show that the width and shape of the
profiles of some diffuse interstellar bands (6196 and 5797 A) apparently depend
on the gas kinetic and rotational temperatures of C2; the profiles are broader
because of the higher values of the gas kinetic and rotational temperatures of
C2. There are also diffuse interstellar bands (4964 and 5850 A) for which this
effect does not exist.Comment: 8 pages, 4 figures, accepted to MNRAS 201
- …