2,542 research outputs found
The runaway instability in general relativistic accretion disks
When an accretion disk falls prey to the runaway instability, a large portion
of its mass is devoured by the black hole within a few dynamical times. Despite
decades of effort, it is still unclear under what conditions such an
instability can occur. The technically most advanced relativistic simulations
to date were unable to find a clear sign for the onset of the instability. In
this work, we present three-dimensional relativistic hydrodynamics simulations
of accretion disks around black holes in dynamical space-time. We focus on the
configurations that are expected to be particularly prone to the development of
this instability. We demonstrate, for the first time, that the fully
self-consistent general relativistic evolution does indeed produce a runaway
instability.Comment: 5 pages, 3 figures, minor corrections to match published version in
MNRAS, +link to animatio
Nasa desalting kit development, phase ii first progress report
NASA desalting kit development - container and processor desig
A Bayesian regression tree approach to identify the effect of nanoparticles' properties on toxicity profiles
We introduce a Bayesian multiple regression tree model to characterize
relationships between physico-chemical properties of nanoparticles and their
in-vitro toxicity over multiple doses and times of exposure. Unlike
conventional models that rely on data summaries, our model solves the low
sample size issue and avoids arbitrary loss of information by combining all
measurements from a general exposure experiment across doses, times of
exposure, and replicates. The proposed technique integrates Bayesian trees for
modeling threshold effects and interactions, and penalized B-splines for dose-
and time-response surface smoothing. The resulting posterior distribution is
sampled by Markov Chain Monte Carlo. This method allows for inference on a
number of quantities of potential interest to substantive nanotoxicology, such
as the importance of physico-chemical properties and their marginal effect on
toxicity. We illustrate the application of our method to the analysis of a
library of 24 nano metal oxides.Comment: Published at http://dx.doi.org/10.1214/14-AOAS797 in the Annals of
Applied Statistics (http://www.imstat.org/aoas/) by the Institute of
Mathematical Statistics (http://www.imstat.org
Exploring the dark sectors via the cooling of white dwarfs
As dense and hot bodies with a well-understood equation of state, white
dwarfs offer a unique opportunity to investigate new physics. In this paper, we
examine the role of dark sectors, which are extensions of the Standard Model of
particle physics that are not directly observable, in the cooling process of
white dwarfs. Specifically, we examine the role of a dark photon, within the
framework of a three-portal Model, in enhancing the neutrino emission during
the cooling process of white dwarfs. We compare this scenario to the energy
release predicted by the Standard Model. By analyzing the parameter space of
dark sectors, our study aims to identify regions that could lead to significant
deviations from the expected energy release of white dwarfs.Comment: 9 pages, 5 figure
Scaling K2. I. Revised Parameters for 222,088 K2 Stars and a K2 Planet Radius Valley at 1.9 R_⊕
Previous measurements of stellar properties for K2 stars in the Ecliptic Plane Input Catalog largely relied on photometry and proper motion measurements, with some added information from available spectra and parallaxes. Combining Gaia DR2 distances with spectroscopic measurements of effective temperatures, surface gravities, and metallicities from the Large Sky Area Multi-Object Fibre Spectroscopic Telescope (LAMOST) DR5, we computed updated stellar radii and masses for 26,838 K2 stars. For 195,250 targets without a LAMOST spectrum, we derived stellar parameters using random forest regression on photometric colors trained on the LAMOST sample. In total, we measured spectral types, effective temperatures, surface gravities, metallicities, radii, and masses for 222,088 A, F, G, K, and M-type K2 stars. With these new stellar radii, we performed a simple reanalysis of 299 confirmed and 517 candidate K2 planet radii from Campaigns 1–13, elucidating a distinct planet radius valley around 1.9 R_⊕, a feature thus far only conclusively identified with Kepler planets, and tentatively identified with K2 planets. These updated stellar parameters are a crucial step in the process toward computing K2 planet occurrence rates
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