185 research outputs found
Protostellar disks and the primitive solar nebula
The objective is to obtain quantitative information on the turbulent transport of mass, angular momentum, and energy under the conditions that characterize the solar nebula, by direct numerical calculations. These calculations were made possible by research conducted on supercomputers (Cray XMP and Cray 2) by the Ames Computational Fluid Dynamics Branch. Techniques were developed that permitted the accurate representation of turbulent flows over the full range of important eddy sizes. So far, these techniques were applied (and verified) primarily in mundane laboratory situations, but they have a strong potential for astrophysical applications. A sequence of numerical experiments were conducted to evaluate the Reynold's stress tensor, turbulent heat transfer rate, turbulent dissipation rate, and turbulent kinetic energy spectrum, as functions of position, for conditions relevant to the solar nebula. Emphasis is placed on the variation of these properties with appropriate nondimensional quantities, so that relations can be derived that will be useful for disk modeling under a variety of hypotheses and initial conditions
The potential for tidally heated icy and temperate moons around exoplanets
Moons of giant planets may represent an alternative to the classical picture
of habitable worlds. They may exist within the circumstellar habitable zone of
a parent star, and through tidal energy dissipation they may also offer
alternative habitable zones, where stellar insolation plays a secondary, or
complementary, role. We investigate the potential extent of stable satellite
orbits around a set of 74 known extrasolar giant planets located beyond 0.6 AU
from their parent stars - where moons should be long-lived with respect to
removal by stellar tides. Approximately 60% of these giant planets can sustain
satellites or moons in bands up to AU in width. For comparison, the
Galiean satellites extend to AU. We investigate the stellar
insolation that moons would experience for these exoplanet systems, and the
implications for sublimation loss of volatiles. We find that between 15 and 27%
of {\em all} known exoplanets may be capable of harboring small, icy, moons. In
addition, some 22-28% of all known exoplanets could harbor moons within a
``sublimation zone'', with insolation temperatures between 273 K and 170 K. A
simplified energy balance model is applied to the situation of temperate moons,
maintained by a combination of stellar insolation and tidal heat flow. We
demonstrate that large moons (M), at orbital radii
commensurate with those of the Galilean satellites, could maintain temperate,
or habitable, surface conditions during episodes of tidal heat dissipation of
the order 1-100 times that currently seen on Io. (Abridged).Comment: 28 pages, 8 Figures, AASTex, Accepted for publication in the
Astrophysical Journa
Nonlinear Outcome of Gravitational Instability in Disks with Realistic Cooling
We consider the nonlinear outcome of gravitational instability in optically
thick disks with a realistic cooling function. We use a numerical model that is
local, razor-thin, and unmagnetized. External illumination is ignored. Cooling
is calculated from a one-zone model using analytic fits to low temperature
Rosseland mean opacities. The model has two parameters: the initial surface
density Sigma_0 and the rotation frequency Omega. We survey the parameter space
and find: (1) The disk fragments when t_c,eff Omega = 1, where t_c,eff is an
effective cooling time defined as the average internal energy of the model
divided by the average cooling rate. This is consistent with earlier results
that used a simplified cooling function. (2) The initial cooling time t_c0 or a
uniform disk with Q = 1 can differ by orders of magnitude from t_c,eff in the
nonlinear outcome. The difference is caused by sharp variations in the opacity
with temperature. The condition t_c0 Omega = 1 therefore does not necessarily
indicate where fragmentation will occur. (3) The largest difference between
t_c,eff and t_c0 is near the opacity gap, where dust is absent and hydrogen is
largely molecular. (4) In the limit of strong illumination the disk is
isothermal; we find that an isothermal version of our model fragments for Q <
1.4. Finally, we discuss some physical processes not included in our model, and
find that most are likely to make disks more susceptible to fragmentation. We
conclude that disks with t_c,eff Omega < 1 do not exist.Comment: 30 pages, 12 figure
High potential x-ray tube
An account is given of further development work on the high potential x-ray tube at the California Institute of Technology. Details of the construction of the tube and its housing are presented. The housing, which is a concrete structure erected on the floor of the high potential laboratory, makes it possible to operate and make observations at close range. The tube has been equipped with a hot cathode and a tungsten target, thus rendering it more suitable for spectrographic work. High speed cathode rays outside of the tube have been obtained by replacing the target by thin windows of mica or metal. Continuous operation is possible over a period of several hours at six hundred kilovolts and with a space current of three to four milliamperes. A comparison between different types of high potential x-ray tubes and of different methods of operation is contained in the discussion
Vertically Self-Gravitating ADAFs in the Presence of Toroidal Magnetic Field
Force due to the self-gravity of the disc in the vertical direction is
considered to study its possible effects on the structure of a magnetized
advection-dominated accretion disc. We present steady-sate self similar
solutions for the dynamical structure of such a type of the accretion flows.
Our solutions imply reduced thickness of the disc because of the self-gravity.
It also imply that the thickness of the disc will increase by adding the
magnetic field strength.Comment: Accepted for publication in Astrophysics and Space Science
A Preliminary Observational Search for Circumbinary Disks Around Cataclysmic Variables
Circumbinary (CB) disks have been proposed as a mechanism to extract orbital
angular momentum from cataclysmic variables (CVs) during their evolution. As
proposed by Taam & Spruit, these disks extend outwards to several a.u. and
should be detected observationally via their infrared flux or by absorption
lines in the ultraviolet spectra of the CV. We have made use of archival
HST/STIS spectra as well as our own near-IR imaging to search for observational
evidence of such CB disks in seven CVs. Based on the null result, we place an
upper limit on the column density of the disk of N_H~10^17 cm^-2.Comment: accepted for publication in the Astronomical Journal (July 2004
Database model and specification of GermOnline Release 2.0, a cross-species community annotation knowledgebase on germ cell differentiation
Summary: GermOnline is a web-accessible relational database that enables life scientists to make a significant and sustained contribution to the annotation of genes relevant for the fields of mitosis, meiosis, germ line development and gametogenesis across species. This novel approach to genome annotation includes a platform for knowledge submission and curation as well as microarray data storage and visualization hosted by a global network of servers. Availability: The database is accessible at http://www.germonline.org/. For convenient world-wide access we have set up a network of servers in Europe (http://germonline.unibas.ch/; http://germonline.igh.cnrs.fr/), Japan (http://germonline.biochem.s.u-tokyo.ac.jp/) and USA (http://germonline.yeastgenome.org/). Supplementary information: Extended documentation of the database is available through the link ‘About GermOnline' at the website
Accretion of low angular momentum material onto black holes: 2D hydrodynamical inviscid case
We report on the first phase of our study of slightly rotating accretion
flows onto black holes. We consider inviscid accretion flows with a spherically
symmetric density distribution at the outer boundary, but with spherical
symmetry broken by the introduction of a small, latitude-dependent angular
momentum. We study accretion flows by means of numerical 2D, axisymmetric,
hydrodynamical simulations. Our main result is that the properties of the
accretion flow do not depend as much on the outer boundary conditions (i.e.,
the amount as well as distribution of the angular momentum) as on the geometry
of the non-accreting matter. The material that has too much angular momentum to
be accreted forms a thick torus near the equator. Consequently, the geometry of
the polar region, where material is accreted (the funnel), and the mass
accretion rate through it are constrained by the size and shape of the torus.
Our results show one way in which the mass accretion rate of slightly rotating
gas can be significantly reduced compared to the accretion of non-rotating gas
(i.e., the Bondi rate), and set the stage for calculations that will take into
account the transport of angular momentum and energy.Comment: LaTeX,to appear in Ap
Origin of volatiles in the Main Belt
We propose a scenario for the formation of the Main Belt in which asteroids
incorporated icy particles formed in the outer Solar Nebula. We calculate the
composition of icy planetesimals formed beyond a heliocentric distance of 5 AU
in the nebula by assuming that the abundances of all elements, in particular
that of oxygen, are solar. As a result, we show that ices formed in the outer
Solar Nebula are composed of a mix of clathrate hydrates, hydrates formed above
50 K and pure condensates produced at lower temperatures. We then consider the
inward migration of solids initially produced in the outer Solar Nebula and
show that a significant fraction may have drifted to the current position of
the Main Belt without encountering temperature and pressure conditions high
enough to vaporize the ices they contain. We propose that, through the
detection and identification of initially buried ices revealed by recent
impacts on the surfaces of asteroids, it could be possible to infer the
thermodynamic conditions that were present within the Solar Nebula during the
accretion of these bodies, and during the inward migration of icy
planetesimals. We also investigate the potential influence that the
incorporation of ices in asteroids may have on their porosities and densities.
In particular, we show how the presence of ices reduces the value of the bulk
density of a given body, and consequently modifies its macro-porosity from that
which would be expected from a given taxonomic type.Comment: Accepted for publication in MNRA
Succeeding against the odds: can schools ‘compensate for society’?
Education researchers, policy-makers and practitioners in the UK have debated the question of what, and how much, schools can do to mitigate the effects of parental background on educational outcomes over the last half a century. A range of programmes, strategies and interventions have been implemented, and continue to be implemented in an effort to ‘break the link’ between socio-economic disadvantage and low educational outcomes, but educational inequalities have persisted. This paper draws on theoretical and empirical research to offer a new analysis of compensatory education in England across three main phases since the 1960s
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