578 research outputs found
A new numerical method to construct binary neutron star initial data
We present a new numerical method for the generation of binary neutron star
initial data using a method along the lines of the the Wilson-Mathews or the
closely related conformal thin sandwich approach. Our method uses six different
computational domains, which include spatial infinity. Each domain has its own
coordinates which are chosen such that the star surfaces always coincide with
domain boundaries. These properties facilitate the imposition of boundary
conditions. Since all our fields are smooth inside each domain, we are able to
use an efficient pseudospectral method to solve the elliptic equations
associated with the conformal thin sandwich approach. Currently we have
implemented corotating configurations with arbitrary mass ratios, but an
extension to arbitrary spins is possible. The main purpose of this paper is to
introduce our new method and to test our code for several different
configurations.Comment: 18 pages, 8 figures, 1 tabl
Thermal and Dynamical Equilibrium in Two-Component Star Clusters
We present the results of Monte Carlo simulations for the dynamical evolution
of star clusters containing two stellar populations with individual masses m1
and m2 > m1, and total masses M1 and M2 < M1. We use both King and Plummer
model initial conditions and we perform simulations for a wide range of
individual and total mass ratios, m2/m1 and M2/M1. We ignore the effects of
binaries, stellar evolution, and the galactic tidal field. The simulations use
N = 10^5 stars and follow the evolution of the clusters until core collapse. We
find that the departure from energy equipartition in the core follows
approximately the theoretical predictions of Spitzer (1969) and Lightman & Fall
(1978), and we suggest a more exact condition that is based on our results. We
find good agreement with previous results obtained by other methods regarding
several important features of the evolution, including the pre-collapse
distribution of heavier stars, the time scale on which equipartition is
approached, and the extent to which core collapse is accelerated by a small
subpopulation of heavier stars. We briefly discuss the possible implications of
our results for the dynamical evolution of primordial black holes and neutron
stars in globular clusters.Comment: 31 pages, including 13 figures, to appear in Ap
Adventures in Friedmann Cosmology: An Educationally Detailed Expansion of the Cosmological Friedmann Equations
The general relativistic cosmological Friedmann equations which describe how
the scale factor of the universe evolves are expanded explicitly to include
energy forms not usually seen. The evolution of the universe as predicted by
the Friedmann equations when dominated by a single, isotropic, stable, static,
perfect-fluid energy form is discussed for different values of its
gravitational pressure to density ratio . These energy forms include phantom
energy (), cosmological constant (), domain walls (),
cosmic strings (), normal matter (), radiation and
relativistic matter (), and a previously little-discussed form of
energy called "ultralight" (). A brief history and possible futures of
Friedmann universes dominated by a single energy form are discussed.Comment: 32 pages, 4 tables; modified version accepted for publication in the
American Journal of Physic
Testing a Simplified Version of Einstein's Equations for Numerical Relativity
Solving dynamical problems in general relativity requires the full machinery
of numerical relativity. Wilson has proposed a simpler but approximate scheme
for systems near equilibrium, like binary neutron stars. We test the scheme on
isolated, rapidly rotating, relativistic stars. Since these objects are in
equilibrium, it is crucial that the approximation work well if we are to
believe its predictions for more complicated systems like binaries. Our results
are very encouraging.Comment: 9 pages (RevTeX 3.0 with 6 uuencoded figures), CRSR-107
Ohm's Law for a Relativistic Pair Plasma
We derive the fully relativistic Ohm's law for an electron-positron plasma.
The absence of non-resistive terms in Ohm's law and the natural substitution of
the 4-velocity for the velocity flux in the relativistic bulk plasma equations
do not require the field gradient length scale to be much larger than the
lepton inertial lengths, or the existence of a frame in which the distribution
functions are isotropic.Comment: 12 pages, plain TeX, Phys. Rev. Lett. 71 3481 (1993
Electrostatic interaction of a pointlike charge with a wormhole
A pointlike electric charge at rest is considered in the spacetime which is a
wormhole connecting two otherwise Minkowskian spaces. The potential (i. e. a
solution of the Maxwell equations) is split into two parts: one of them depends
only on the value and location of the charge, while the other, on the contrary,
does not change when the charge is quasistatically moved. Correspondingly, the
former is interpreted as being generated by the charge, and the latter as being
source-free. It is shown that all source-free potentials differ in the flux
through the throat (no "multipoles without multipoles"), which enables one to
interpret the flux as the "charge" of the wormhole in agreement with Wheeler's
concept of "charge without charge". The potential generated by the charge
differs from Coulomb's and thus a force (called "self-force") acts on the
charge even in the absence of the source-free field. This force is found
explicitly in the limit of vanishing throat length. The result differs from
that obtained recently by Khusnutdinov and Bakhmatov.Comment: The published version: 1) the regularity is proven 2) the part is
rewritten explaining where is the error in Khusnutdinov and Bakhmatov's
resul
Bernstein modes in a weakly relativistic electron-positron plasma
The kinetic theory of weakly relativistic electron-positron plasmas, producing dispersion relations for the electrostatic Bernstein modes was addressed. The treatment presented preserves the full momentum dependence of the cyclotron frequency, albeit with a relaxation on the true relativistic form of the distribution function. The implications of this new treatment were confined largely to astrophysical plasmas, where relativistic electronpositron plasmas occur naturally
A Review of Antimicrobial Therapy for Infectious Uveitis of the Posterior Segment
Treatment of infectious posterior uveitis represents a therapeutic challenge for ophthalmologists. The eye is a privileged site, maintained by blood ocular barriers, which limits penetration of systemic antimicrobials into the posterior segment. In addition, topical and subconjunctival therapies are incapable of producing sufficient drug concentrations, intraocularly. Posterior infectious uveitis can be caused by bacteria, virus, fungi, or protozoa. Mode of treatment varies greatly based on the infectious etiology. Certain drugs have advantages over others in the treatment of infectious uveitis. Topical and systemic therapies are often employed in the treatment of ocular infection, yet the route of treatment can have limitations based on penetration, concentration, and duration. The introduction of intravitreal antimicrobial therapy has advanced the management of intraocular infections. Being able to bypass blood-ocular barriers allows high drug concentrations to be delivered directly to the posterior segment with minimal systemic absorption. However, because the difference between the therapeutic and the toxic doses of some antimicrobial drugs falls within a narrow concentration range, intravitreal therapy could be associated with ocular toxicity risks. In many cases of infectious uveitis, combination of intravitreal and systemic therapies are necessary. In this comprehensive review, the authors aimed at reviewing clinically relevant data regarding intraocular and systemic antimicrobial therapy for posterior segment infectious uveitis. The review also discussed the evolving trends in intraocular treatment, and elaborated on antibiotic pharmacokinetics and pharmacodynamics, efficacy, and adverse effects
A Review of Antimicrobial Therapy for Infectious Uveitis of the Posterior Segment
Treatment of infectious posterior uveitis represents a therapeutic challenge for ophthalmologists. The eye is a privileged site, maintained by blood ocular barriers, which limits penetration of systemic antimicrobials into the posterior segment. In addition, topical and subconjunctival therapies are incapable of producing sufficient drug concentrations, intraocularly. Posterior infectious uveitis can be caused by bacteria, virus, fungi, or protozoa. Mode of treatment varies greatly based on the infectious etiology. Certain drugs have advantages over others in the treatment of infectious uveitis. Topical and systemic therapies are often employed in the treatment of ocular infection, yet the route of treatment can have limitations based on penetration, concentration, and duration. The introduction of intravitreal antimicrobial therapy has advanced the management of intraocular infections. Being able to bypass blood-ocular barriers allows high drug concentrations to be delivered directly to the posterior segment with minimal systemic absorption. However, because the difference between the therapeutic and the toxic doses of some antimicrobial drugs falls within a narrow concentration range, intravitreal therapy could be associated with ocular toxicity risks. In many cases of infectious uveitis, combination of intravitreal and systemic therapies are necessary. In this comprehensive review, the authors aimed at reviewing clinically relevant data regarding intraocular and systemic antimicrobial therapy for posterior segment infectious uveitis. The review also discussed the evolving trends in intraocular treatment, and elaborated on antibiotic pharmacokinetics and pharmacodynamics, efficacy, and adverse effects
The evolution of a supermassive binary caused by an accretion disc
The interaction of a massive binary and a non-self-gravitating circumbinary
accretion disc is considered. The shape of the stationary twisted disc produced
by the binary is calculated. It is shown that the inner part of the disc must
lie in the binary orbital plane for any value of viscosity.
When the inner disc midplane is aligned with the binary orbital plane on the
scales of interest and it rotates in the same sense as the binary, the
modification of the disc structure and the rate of decay of the binary orbit,
assumed circular, due to tidal exchange of angular momentum with the disc, are
calculated. It is shown that the modified disc structure is well described by a
self-similar solution of the non-linear diffusion equation governing the
evolution of the disc surface density. The calculated time scale for decay of
the binary orbit is always smaller than the "accretion" time ( is the mass of the secondary component, and is the disc
accretion rate), and is determined by ratio of secondary mass , assumed to
be much smaller than the primary mass, the disc mass inside the initial binary
orbit, and the form of viscosity in the disc.Comment: to be published in MNRA
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