27,672 research outputs found
Observational Evidence for an Age Dependence of Halo Bias
We study the dependence of the cross-correlation between galaxies and galaxy
groups on group properties. Confirming previous results, we find that the
correlation strength is stronger for more massive groups, in good agreement
with the expected mass dependence of halo bias. We also find, however, that for
groups of the same mass, the correlation strength depends on the star formation
rate (SFR) of the central galaxy: at fixed mass, the bias of galaxy groups
decreases as the SFR of the central galaxy increases. We discuss these findings
in light of the recent findings by Gao et al (2005) that halo bias depends on
halo formation time, in that halos that assemble earlier are more strongly
biased. We also discuss the implication for galaxy formation, and address a
possible link to galaxy conformity, the observed correlation between the
properties of satellite galaxies and those of their central galaxy.Comment: 4 pages, 4 figures, Accepted for publication in ApJ Letters. Figures
3 and 4 replaced. The bias dependence on the central galaxy luminosity is
omitted due to its sensitivity to the mass mode
Independent Orbiter Assessment (IOA): FMEA/CIL assessment
The results of the Independent Orbiter Assessment (IOA) of the Failure Modes and Effects Analysis (FMEA) and Critical Items List (CIL) are presented. Direction was given by the Orbiter and GFE Projects Office to perform the hardware analysis and assessment using the instructions and ground rules defined in NSTS 22206. The IOA analysis features a top-down approach to determine hardware failure modes, criticality, and potential critical items. To preserve independence, the anlaysis was accomplished without reliance upon the results contained within the NASA and prime contractor FMEA/CIL documentation. The assessment process compares the independently derived failure modes and criticality assignments to the proposed NASA Post 51-L FMEA/CIL documentation. When possible, assessment issues are discussed and resolved with the NASA subsystem managers. The assessment results for each subsystem are summarized. The most important Orbiter assessment finding was the previously unknown stuck autopilot push-button criticality 1/1 failure mode, having a worst case effect of loss of crew/vehicle when a microwave landing system is not active
The Formation of Galactic Disks
We study the population of galactic disks expected in current hierarchical
clustering models for structure formation. A rotationally supported disk with
exponential surface density profile is assumed to form with a mass and angular
momentum which are fixed fractions of those of its surrounding dark halo. We
assume that haloes respond adiabatically to disk formation, and that only
stable disks can correspond to real systems. With these assumptions the
predicted population can match both present-day disks and the damped Lyman
alpha absorbers in QSO spectra. Good agreement is found provided: (i) the
masses of disks are a few percent of those of their haloes; (ii) the specific
angular momenta of disks are similar to those of their haloes; (iii)
present-day disks were assembled recently (at z<1). In particular, the observed
scatter in the size-rotation velocity plane is reproduced, as is the slope and
scatter of the Tully-Fisher relation. The zero-point of the TF relation is
matched for a stellar mass-to-light ratio of 1 to 2 h in the I-band, consistent
with observational values derived from disk dynamics. High redshift disks are
predicted to be small and dense, and could plausibly merge together to form the
observed population of elliptical galaxies. In many (but not all) currently
popular cosmogonies, disks with rotation velocities exceeding 200 km/s can
account for a third or more of the observed damped Lyman alpha systems at
z=2.5. Half of the lines-of-sight to such systems are predicted to intersect
the absorber at r>3kpc/h and about 10% at r>10kpc/h. The cross-section for
absorption is strongly weighted towards disks with large angular momentum and
so large size for their mass. The galaxy population associated with damped
absorbers should thus be biased towards low surface brightness systems.Comment: 47 pages, Latex, aaspp4.sty, 14 figs included, submitted to MNRA
The Structure and Clustering of Lyman Break Galaxies
The number density and clustering properties of Lyman-break galaxies (LBGs)
are consistent with them being the central galaxies of the most massive dark
halos present at z~3. This conclusion holds in all currently popular
hierarchical models for structure formation, and is almost independent of the
global cosmological parameters. We examine whether the sizes, luminosities,
kinematics and star-formation rates of LBGs are also consistent with this
identification. Simple formation models tuned to give good fits to low redshift
galaxies can predict the distribution of these quantities in the LBG
population. The LBGs should be small (with typical half-light radii of 0.6-2
kpc/h), should inhabit haloes of moderately high circular velocity (180-290
km/s) but have low stellar velocity dispersions (70-120 km/s) and should have
substantial star formation rates (15-100 Msun/yr). The numbers here refer to
the predicted median values in the LBG sample of Adelberger et al. (1998); the
first assumes an Omega=1 universe and the second a flat universe with
Omega=0.3. For either cosmology these predictions are consistent with the
current (rather limited) observational data. Following the work of Kennicutt
(1998) we assume stars to form more rapidly in gas of higher surface density.
This predicts that LBG samples should preferentially contain objects with low
angular momentum, and so small size, for their mass. In contrast, samples of
damped Lyman alpha systems (DLSs), should be biased towards objects with large
angular momentum. Bright LBGs and DLSs may therefore form distinct populations,
with very different sizes and star formation rates, LBGs being smaller and more
metal-rich than DLSs of similar mass and redshift.Comment: 27 pages, 9 figures, MNRAS submitte
The Radial Distribution of Galaxies in LCDM clusters
We study the radial distribution of subhalos and galaxies using
high-resolution cosmological simulations of galaxy clusters formed in the
concordance LCDM cosmology. In agreement with previous studies, we find that
the radial distribution of subhalos is significantly less concentrated than
that of the dark matter, when subhalos are selected using their present-day
gravitationally bound mass. We show that the difference in the radial
distribution is not a numerical artifact and is due to tidal stripping. The
subhalos in the cluster core lose more than 70% of their initial mass since
accretion, while the average tidal mass loss for halos near the virial radius
is ~30%. This introduces a radial bias in the spatial distribution of subhalos
when they are selected using their tidally truncated mass. We demonstrate that
the radial bias disappears almost entirely if subhalos are selected using their
mass or circular velocity at the accretion epoch. The comparisons of the
results of dissipationless simulations to the observed distribution of galaxies
in clusters are therefore sensitive to the selection criteria used to select
subhalo samples. Using the simulations that include cooling and starformation,
we show that the radial distribution of subhalos is in reasonable agreement
with the observed radial distribution of galaxies in clusters for
0.1<R/R200<2.0, if subhalos are selected using the stellar mass of galaxies.
The radial bias is minimized in this case because the stars are located in the
centers of dark matter subhalos and are tightly bound. The stellar mass of an
object is therefore approximately conserved as the dark matter is stripped from
the outer regions. Nevertheless, the concentration of the radial distribution
of galaxies is systematically lower than that of the dark matter.Comment: submitted to ApJ, 12 pages, 12 figure
Holistic educational development integrated through mechatronics design
This paper presents an approach in educational development of resources and programs based on multidisciplinary concept. The development is built around the process of mechatronics program delivery that is currently introduced in tertiary education within RMIT University. Mechatronics is a multidisciplinary engineering area that incorporates mechanical, electrical, electronics, computer and information systems. Students studying Mechatronics Engineering expand their knowledge of various systems and scientific areas and integrate them in a working system. Through work integrated learning, students are encouraged to obtain new knowledge and skills by doing the job, not just learning from the textbooks and attending lectures. Subject material is delivered in variety of ways, started with face-to-face delivery, seminars, tutorials and lab sessions. The key component of this education is project work conducted in small teams. Finally, University conducts surveys after every single subject delivery and the results of the latest survey are presented here. According to the survey, students are extremely satisfied with the new approach that focuses on problem solving, project and exploration work
Nearby Gas-Rich Low Surface Brightness Galaxies
We examine the Fisher-Tully cz<1000 km/s galaxy sample to determine whether
it is a complete and representative sample of all galaxy types, including low
surface brightness populations, as has been recently claimed. We find that the
sample is progressively more incomplete for galaxies with (1) smaller physical
diameters at a fixed isophote and (2) lower HI masses. This is likely to lead
to a significant undercounting of nearby gas-rich low surface brightness
galaxies. However, through comparisons to other samples we can understand how
the nearby galaxy counts need to be corrected, and we see some indications of
environmental effects that probably result from the local high density of
galaxies.Comment: 12 page, 2 figures, to appear in Ap
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