19 research outputs found
G 112-29 (=NLTT 18149), a Very Wide Companion to GJ 282 AB with a Common Proper Motion, Common Parallax, Common Radial Velocity and Common Age
We have made a search for common proper motion (CPM) companions to the wide
binaries in the solar vicinity. We found that the binary GJ 282AB has a very
distant CPM companion (NLTT 18149) at a separation s=1.09 \arcdeg. Improved
spectral types and radial velocities are obtained, and ages determined for the
three components. The Hipparcos trigonometric parallaxes and the new radial
velocities and ages turn out to be very similar for the three stars, and
provide strong evidence that they form a physical system. At a projected
separation of 55733AU from GJ 282AB, NLTT 18149 ranks among the widest physical
companions known.Comment: 13 pages, 3 figures, submmited to Ap
On the Reported Death of the MACHO Era
We present radial velocity measurements of four wide halo binary candidates
from the sample in Chaname & Gould (2004; CG04) which, to date, is the only
sample containing a large number of such candidates. The four candidates that
we have observed have projected separations >0.1 pc, and include the two widest
binaries from the sample, with separations of 0.45 and 1.1 pc. We confirm that
three of the four CG04 candidates are genuine, including the one with the
largest separation. The fourth candidate, however, is spurious at the 5-sigma
level. In the light of these measurements we re-examine the implications for
MACHO models of the Galactic halo. Our analysis casts doubt on what MACHO
constraints can be drawn from the existing sample of wide halo binaries.Comment: 6 Pages, 4 Figures, Accepted for MNRAS Letter
The Ionized Gas Kinematics of the LMC-Type Galaxy NGC 1427A in the Fornax Cluster
NGC 1427A is a LMC-like irregular galaxy in the Fornax cluster with an
extended pattern of strong star formation around one of its edges, which is
probably due to some kind of interaction with the cluster environment. We
present H-alpha velocities within NGC 1427A, obtained through long-slit
spectroscopy at seven different positions, chosen to fall on the brightest HII
regions of the galaxy. Due to its location very near the center of the cluster
this object is an excellent candidate to study the effects that the cluster
environment has on gas-rich galaxies embedded in it. The rotation of NGC 1427A
is modeled in two different ways. The global ionized gas kinematics is
reasonably well described by solid-body rotation, although on small scales it
shows a chaotic behaviour. In this simple model, the collision with a smaller
member of the cluster as being responsible for the peculiar morphology of NGC
1427A is very unlikely, since the only candidate intruder falls smoothly into
the general velocity pattern of the main galaxy. In a more elaborate model, for
which we obtain a better solution, this object does not lie in the same plane
of NGC 1427A, in which case we identify it as a satellite bound to the galaxy.
These results are discussed in the context of a normal irregular versus one
interacting with some external agent. Based on several arguments and
quantitative estimates, we argue that the passage through the hot intracluster
gas of the Fornax cluster is a very likely scenario to explain the
morphological properties of NGC 1427A.Comment: 31 pages, LaTeX2e, uses aas2pp4.sty and psfig.sty, including 7
Postscript figures; accepted for publication in ApJ, Vol. 530, February 200
Disk and Halo Wide Binaries from the Revised Luyten Catalog: Probes of Star Formation and MACHO Dark Matter
We present a catalog of 1147 candidate common proper motion binaries selected
from the revised New Luyten Two-Tenths Catalog. Among these, we identify 999
genuine physical pairs using the measured proper-motion difference and the
relative positions of each binary's components on a reduced proper-motion (RPM)
diagram. The RPM positions also serve to classify them as either disk
main-sequence (801), halo subdwarf (116), or pairs containing at least one
white dwarf (82). The disk and halo samples are complete to separations of
\theta=500" and \theta=900", which correspond to ~0.1 pc and ~1 pc,
respectively. At wide separations, both distributions are well described by
single power laws, dN/d\theta ~ \theta^{-\alpha}: \alpha=1.67+-0.07 for the
disk and \alpha=1.55+-0.10 for the halo. The fact that these distributions have
similar slopes (and similar normalizations as well) argues for similarity of
the star-formation conditions of these two populations. The fact that the halo
binaries obey a single power law out to ~1 pc permits strong constraints on
halo dark-matter candidates. At somewhat closer separations (10"<\theta<25"),
the disk distribution shows a pronounced flattening, which is detected at very
high statistical significance and is not due to any obvious systematic effect.
We also present a list of 11 previously unknown halo stars with parallaxes that
are recognized here as companions of Hipparcos stars.Comment: 56 pages, 16 figures; replaced with version accepted for publication
in Ap
Wide binaries as a critical test of Classical Gravity
Modified gravity scenarios where a change of regime appears at acceleration
scales have been proposed. Since for systems the
acceleration drops below at scales of around 7000 AU, a statistical
survey of wide binaries with relative velocities and separations reaching
AU and beyond should prove useful to the above debate. We apply the
proposed test to the best currently available data. Results show a constant
upper limit to the relative velocities in wide binaries which is independent of
separation for over three orders of magnitude, in analogy with galactic flat
rotation curves in the same acceleration regime. Our results are
suggestive of a breakdown of Kepler's third law beyond
scales, in accordance with generic predictions of modified gravity theories
designed not to require any dark matter at galactic scales and beyond.Comment: accepted for publication in EPJ
Primordial Black Holes: sirens of the early Universe
Primordial Black Holes (PBHs) are, typically light, black holes which can
form in the early Universe. There are a number of formation mechanisms,
including the collapse of large density perturbations, cosmic string loops and
bubble collisions. The number of PBHs formed is tightly constrained by the
consequences of their evaporation and their lensing and dynamical effects.
Therefore PBHs are a powerful probe of the physics of the early Universe, in
particular models of inflation. They are also a potential cold dark matter
candidate.Comment: 21 pages. To be published in "Quantum Aspects of Black Holes", ed. X.
Calmet (Springer, 2014
Abundance Anomalies and Rotational Evolution of Low Mass Red Giants: A Maximal Mixing Approach
(ABRIDGED) We use a fully self-consistent evolutionary code to follow the
rotational evolution of red giants, making a comprehensive attempt to assess
the role of rotationally induced mixing in the development of abundance
anomalies in giants with a range of masses and metallicities in stellar
clusters and the field. Unlike most previous work, we do not focus on the
determination of combinations of mixing rate and depth that reproduce the data
on a particular stellar type. Instead, we concentrate on the more fundamental
problem of the simultaneous reproduction of the CNO surface patterns in both
Population I and Population II giants using the same physics and models. A
general result of all our models is that rotational mixing, although present in
small amounts, is inefficient on the lower RGB independently of any inhibiting
effect of composition barriers. Models with differentially rotating envelopes
are able to reproduce the carbon isotope data on M67 giants with initial
rotation rates adequate to their progenitors, but fail to do so for open
clusters of larger turnoff mass as well as for metal-poor giants in the field
and globular clusters. Possible solutions are discussed. Our favored scenario
is one in which the overall strength of canonical extra mixing has been
underestimated by existent derivations, but which additionally needs to be
coupled with a much lower efficiency for rotational mixing among the rapidly
rotating open cluster giants than in the slowly rotating ones in the field and
globular clusters. We hypothesize that this last requirement is provided by the
interaction between convection and rotation in the envelopes of giants, in the
sense that rapidly rotating stars would develop much shallower angular velocity
profiles in their envelopes than do slowly rotating stars.Comment: 83 pages, 21 figures; replaced with version accepted for publication
in the Ap