3,885 research outputs found
Gas Giant Protoplanets Formed by Disk Instability in Binary Star Systems
We present a suite of three dimensional radiative gravitational hydrodynamics
models suggesting that binary stars may be quite capable of forming planetary
systems similar to our own. The new models with binary companions do not employ
any explicit artificial viscosity, and also include the third (vertical)
dimension in the hydrodynamic calculations, allowing for transient phases of
convective cooling. The calculations of the evolution of initially marginally
gravitationally stable disks show that the presence of a binary star companion
may actually help to trigger the formation of dense clumps that could become
giant planets. We also show that in models without binary companions, which
begin their evolution as gravitationally stable disks, the disks evolve to form
dense rings, which then break-up into self-gravitating clumps. These latter
models suggest that the evolution of any self-gravitating disk with sufficient
mass to form gas giant planets is likely to lead to a period of disk
instability, even in the absence of a trigger such as a binary star companion.Comment: 52 pages, 28 figure
Extrasolar planet taxonomy: a new statistical approach
In this paper we present the guidelines for an extrasolar planet taxonomy.
The discovery of an increasing number of extrasolar planets showing a vast
variety of planetary parameters, like Keplerian orbital elements and
environmental parameters, like stellar masses, spectral types, metallicity
etc., prompts the development of a planetary taxonomy. In this work via
principal component analysis followed by hierarchical clustering analysis, we
report the definition of five robust groups of planets. We also discuss the
physical relevance of such analysis, which may provide a valid basis for
disentangling the role of the several physical parameters involved in the
processes of planet formation and subsequent evolution. For instance, we were
able to divide the hot Jupiters into two main groups on the basis of their
stellar masses and metallicities. Moreover, for some groups, we find strong
correlations between metallicity, semi-major axis and eccentricity. The
implications of these findings are discussed.Comment: accepted for publication on Ap
Long-term tidal evolution of short-period planets with companions
Of the fourteen transiting extrasolar planetary systems for which radii have
been measured, at least three appear to be considerably larger than theoretical
estimates suggest. It has been proposed by Bodenheimer, Lin & Mardling that
undetected companions acting to excite the orbital eccentricity are responsible
for these oversized planets, as they find new equilibrium radii in response to
being tidally heated. In the case of HD 209458, this hypothesis has been
rejected by some authors because there is no sign of such a companion at the 5
m/s level, and because it is difficult to say conclusively that the
eccentricity is non-zero. Transit timing analysis [...]. Whether or not a
companion is responsible for the large radius of HD 209458b, almost certainly
some short-period systems have companions which force their eccentricities to
nonzero values. This paper is dedicated to quantifying this effect.
The eccentricity of a short-period planet will only be excited as long as its
(non-resonant) companion's eccentricity is non-zero. Here we show that the
latter decays on a timescale which depends on the structure of the interior
planet, a timescale which is often shorter than the lifetime of the system.
This includes Earth-mass planets in the habitable zones of some stars. We
determine which configurations are capable of sustaining significant
eccentricity for at least the age of the system, and show that these include
systems with companion masses as low as a fraction of an Earth mass. The
orbital parameters of such companions are consistent with recent calculations
which show that the migration process can induce the formation of low mass
planets external to the orbits of hot Jupiters. Systems with inflated planets
are therefore good targets in the search for terrestrial planets.Comment: 25 pages, 19 figures. Accepted for publication in MNRA
Increased concentration of an apparently identical cellular protein in cells transformed by either Abelson murine leukemia virus or other transforming agents
Abelson murine leukemia virus (A-MuLV)-transformed cells, simian virus 40 (SV40)-transformed cells, and chemically transformed cells all have increased levels of a 50,000-molecular-weight host cell protein. The protein was detected with sera raised to the A-MuLV-transformed and chemically transformed cells and was tightly bound to T-antigen in extracts of SV40-transformed cells. Partial protease digests showed that the proteins from all three sources were indistinguishable. The three proteins were phosphorylated in cells, and the linkage of phosphate to the A-MuLV-associated P50 was to a serine residue. By immunofluorescence methods, P50-related protein was found on the surface of both normal lymphoid cells and A-MuLV-transformed lymphoid cells, but cell fractionation showed that the majority of P50 was free in the cytoplasm of the transformed cells. Immunofluorescence also showed that P50 was found in granules in the cytoplasm of both untransformed and SV40-transformed fibroblasts. Other cells gave indistinct patterns. Cocapping experiments showed that the A-MuLV-specified P120 protein is weakly associated with the surface P50-related protein of lymphoid cells, but no association of P120 and P50 could be demonstrated by immunoprecipitation methods. Although a monoclonal antiserum to P50 was used in many of these studies, the identity of the bulk P50 protein with the molecules that are reactive at the cell surface requires further study
Dynamical constraints on the origin of the moon
Six different categories of models for the formation of the moon within the context of the general theory of terrestial planet formation by the accumulation of protoplanets are discussed. These catagories are: (1) rotational fission; (2) precipitation fission; (3) intact capture; (4) disintegrative capture; (5) binary accretion; and (6) giant impact accretion. It appears that the only plausable mechanism proposed thus far involves the formation of the Moon following a giant impact that ejects portions of the differentiated Earth's mantle and parts of the impacting body into circumterrestrial orbit
Phase noise measurements of the 400-kW, 2.115-GHz (S-band) transmitter
The measurement theory is described and a test method to perform phase noise verification using off-the-shelf components and instruments is presented. The measurement technique described consists of a double-balanced mixer used as phase detector, followed by a low noise amplifier. An FFT spectrum analyzer is then used to view the modulation components. A simple calibration procedure is outlined that ensures accurate measurements. A block diagram of the configuration is presented as well as actual phase noise data from the 400 kW, 2.115 GHz (S-band) klystron transmitter
Flux-Limited Diffusion Approximation Models of Giant Planet Formation by Disk Instability
Both core accretion and disk instability appear to be required as formation
mechanisms in order to explain the entire range of giant planets found in
extrasolar planetary systems. Disk instability is based on the formation of
clumps in a marginally-gravitationally unstable protoplanetary disk. These
clumps can only be expected to contract and survive to become protoplanets if
they are able to lose thermal energy through a combination of convection and
radiative cooling. Here we present several new three dimensional, radiative
hydrodynamics models of self-gravitating protoplanetary disks, where radiative
transfer is handled in the flux-limited diffusion approximation. We show that
while the flux-limited models lead to higher midplane temperatures than in a
diffusion approximation model without the flux-limiter, the difference in
temperatures does not appear to be sufficiently high to have any significant
effect on the formation of self-gravitating clumps. Self-gravitating clumps
form rapidly in the models both with and without the flux-limiter. These models
suggest that the reason for the different outcomes of numerical models of disk
instability by different groups cannot be attributed solely to the handling of
radiative transfer, but rather appears to be caused by a range of numerical
effects and assumptions. Given the observational imperative to have disk
instability form at least some extrasolar planets, these models imply that disk
instability remains as a viable giant planet formation mechanism.Comment: 30 pages, 15 figures. Astrophysical Journal, in press (May 10 issue
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