2,277 research outputs found
Mechanism related to the lateral rectus muscle capable of retracting the outer canthus of the eye
This is the author's PDF version of an article published in British journal of ophthamology© 1994. The definitive version is available at bjo.bmj.comThis article discusses a case report of a fibromembranous slip arising from the belly of the left lateral rectus muscle which was discovered in a male subject
Does feedback help or hinder star formation? The effect of photoionisation on star formation in Giant Molecular Clouds
We investigated the effect of photoionising feedback inside turbulent
star-forming clouds, comparing the resultant star formation in both idealised
profiles and more realistic cloud structures drawn from a global galaxy
simulation. We performed a series of numerical simulations which compared the
effect of star formation alone, photoionisation and photoionisation plus
supernovae feedback. In the idealised cloud, photoionisation suppresses gas
fragmentation at early times, resulting in the formation of more massive stars
and an increase in the star formation efficiency. At later times, the dispersal
of the dense gas causes the radiative feedback effect to switch from positive
to negative as the star formation efficiency drops. In the cloud extracted from
the global simulation, the initial cloud is heavily fragmented prior to the
stellar feedback beginning and is largely structurally unaffected by the late
injection of radiation energy. The result is a suppression of the star
formation. We conclude that the efficiency of feedback is heavily dependent on
the gas structure, with negative feedback dominating when the density is high.Comment: Accepted to MNRA
Environmental dependence of star formation induced by cloud collisions in a barred galaxy
Cloud collision have been proposed as a way to link the small-scale star
formation process with the observed global relation between the surface star
formation rate and gas surface density. We suggest that this model can be
improved further by allowing the productivity of such collisions to depend on
the relative velocity of the two clouds. Our adjustment implements a simple
step function that results in the most successful collisions being at the
observed velocities for triggered star formation. By applying this to a high
resolution simulation of a barred galaxy, we successfully reproduce the
observational result that the star formation efficiency (SFE) in the bar is
lower than that in the spiral arms. This is not possible when we use an
efficiency dependent on the internal turbulence properties of the clouds. Our
results suggest that high velocity collisions driven by the gravitational pull
of the clouds are responsible for the low bar SFE.Comment: 6 pages, 4 figures. Accepted for publication in MNRAS Letter
Star Formation in Disk Galaxies. III. Does stellar feedback result in cloud death?
Stellar feedback, star formation and gravitational interactions are major
controlling forces in the evolution of Giant Molecular Clouds (GMCs). To
explore their relative roles, we examine the properties and evolution of GMCs
forming in an isolated galactic disk simulation that includes both localised
thermal feedback and photoelectric heating. The results are compared with the
three previous simulations in this series which consists of a model with no
star formation, star formation but no form of feedback and star formation with
photoelectric heating in a set with steadily increasing physical effects. We
find that the addition of localised thermal feedback greatly suppresses star
formation but does not destroy the surrounding GMC, giving cloud properties
closely resembling the run in which no stellar physics is included. The
outflows from the feedback reduce the mass of the cloud but do not destroy it,
allowing the cloud to survive its stellar children. This suggests that weak
thermal feedback such as the lower bound expected for supernova may play a
relatively minor role in the galactic structure of quiescent Milky Way-type
galaxies, compared to gravitational interactions and disk shear.Comment: 15 pages, 15 figures, accepted for publication in Ap
Formation of an embryonic supermassive star in the first galaxy
We studied the gravitational collapse of a warm (~8000 K) primordial-gas
cloud as a candidate progenitor for a supermassive star (SMS; >10^5 Msun) using
a three-dimensional hydrodynamical simulation, including all the relevant
cooling processes of both H_2 and H, which can potentially induce cloud
fragmentation. This is the first simulation of this kind to resolve protostar
formation. We find that the cloud undergoes runaway collapse without a major
episode of fragmentation. Although the H_2 fraction jumps by a large factor via
the three-body reaction at ~10^-13 g/cm^3, its cooling remains inefficient due
to the optical thickness, and the temperature remains >3000 K. When the central
core of the cloud becomes opaque to continuum radiation at ~10^-8 g/cm^3, a
hydrostatic protostar with ~0.2 Msun is formed. The protostar grows to the mass
~1 Msun and the radius ~2 AU within ~1 yr via rapid accretion of dense
filamentary flows. With high accretion rate ~2 Msun/yr, the protostar is
expected to turn into a SMS within its lifetime, eventually collapsing to a
seed for the supermassive black hole observed in the early Universe at z~7.Comment: 6 pages, 6 figures, Accepted for publication in MNRA
Development of an RF IV waveform based stress test procedure for use on GaN HFETs
This paper reports on the development of an RF IV waveform based stress test procedure. DC and low-voltage RF characterisation was carried out before and after high power RF stress. RF waveform measurements showed that the exact change in the RF load line induced during RF degradation cannot be directly inferred from the DC or low power RF measurement. The RF degradation takes the form of a knee-walkout, a small pinch-off shift consistent with charge trapping and defect generation, and in addition gate leakage occurs once the RF voltage exceeds a critical voltage
Gas and stellar spiral structures in tidally perturbed disc galaxies
Tidal interactions between disc galaxies and low mass companions are an
established method for generating galactic spiral features. In this work we
present a study of the structure and dynamics of spiral arms driven in
interactions between disc galaxies and perturbing companions in 3-D
N-body/smoothed hydrodynamical numerical simulations. Our specific aims are to
characterize any differences between structures formed in the gas and stars
from a purely hydrodynamical and gravitational perspective, and to find a
limiting case for spiral structure generation. Through analysis of a number of
different interacting cases, we find that there is very little difference
between arm morphology, pitch angles and pattern speeds between the two media.
The main differences are a minor offset between gas and stellar arms, clear
spurring features in gaseous arms, and different radial migration of material
in the stronger interacting cases. We investigate the minimum mass of a
companion required to drive spiral structure in a galactic disc, finding the
limiting spiral generation cases with companion masses of the order
, equivalent to only 4% of the stellar disc mass, or 0.5%
of the total galactic mass of a Milky Way analogue.Comment: 20 pages, 23 figures, accepted for publication by MNRA
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