3,929 research outputs found
Recent star formation history of the Large and Small Magellanic Clouds
We traced the age of the last star formation event (LSFE) in the inner Large
& Small Magellanic Cloud (L&SMC) using the photometric data from the Optical
Gravitational Lensing Experiment (OGLE-III) and the Magellanic Cloud
Photometric Survey (MCPS). The LSFE is estimated from the main-sequence turn
off point in the color-magnitude diagram (CMD) of a region. Extinction
corrected turn off magnitude is converted to age, which represents the LSFE in
a region. The spatial map of the LSFE age shows that the star formation has
shrunk to the central regions in the last 100Myr in both the galaxies. The
location and age of LSFE is found to correlate well with those of the star
cluster in both the Clouds. The SMC map shows two separate concentrations of
young star formation. We detect peaks of star formation at 0-10, 90-100Myr in
the LMC, and 0-10, 50- 60Myr in the SMC. The quenching of star formation in the
LMC is found to be asymmetric with respect to the optical center such that most
of the young star forming regions are located to the north and east. On
deprojecting the data on the LMC plane, the recent star formation appears to be
stretched in the north-east direction and the HI gas is found to be distributed
preferentially in the North. The centroid is found to shift to north in
200-40Myr, and to north-east in the last 40Myr. In the SMC, we detect a shift
in centroid of population of 500-40Myr in the direction of the LMC. We propose
that the HI gas in the LMC is pulled to the north of the LMC in the last 200Myr
due to the gravitational attraction of our Galaxy at the time of perigalactic
passage. The shifted HI gas is preferentially compressed in the north during
200-40Myr and in the north-east in the last 40Myr, due to the motion of the LMC
in the Galactic halo. The recent star formation in the SMC is due to the
combined gravitational effect of the LMC and the perigalactic passage.Comment: Accepted to A&A on August 31, 201
Ultra-fast escape maneuver of an octopus-inspired robot
We design and test an octopus-inspired flexible hull robot that demonstrates
outstanding fast-starting performance. The robot is hyper-inflated with water,
and then rapidly deflates to expel the fluid so as to power the escape
maneuver. Using this robot we verify for the first time in laboratory testing
that rapid size-change can substantially reduce separation in bluff bodies
traveling several body lengths, and recover fluid energy which can be employed
to improve the propulsive performance. The robot is found to experience speeds
over ten body lengths per second, exceeding that of a similarly propelled
optimally streamlined rigid rocket. The peak net thrust force on the robot is
more than 2.6 times that on an optimal rigid body performing the same maneuver,
experimentally demonstrating large energy recovery and enabling acceleration
greater than 14 body lengths per second squared. Finally, over 53% of the
available energy is converted into payload kinetic energy, a performance that
exceeds the estimated energy conversion efficiency of fast-starting fish. The
Reynolds number based on final speed and robot length is .
We use the experimental data to establish a fundamental deflation scaling
parameter which characterizes the mechanisms of flow control via
shape change. Based on this scaling parameter, we find that the fast-starting
performance improves with increasing size.Comment: Submitted July 10th to Bioinspiration & Biomimetic
Business Intelligence And Its Impact Towards The Performance Of The Local Manufacturing Enterprises.
Salah satu cabaran terbesar yang dialami oleh dunia korporat masa kini ialah mengurus informasi.
One of the biggest challenges presently characterizing today’s corporate context is the management of information due to scarcity of information
Star Clusters in the Magellanic Clouds-1: Parameterisation and Classification of 1072 Clusters in the LMC
We have introduced a semi-automated quantitative method to estimate the age
and reddening of 1072 star clusters in the Large Magellanic Cloud (LMC) using
the Optical Gravitational Lensing Experiment (OGLE) III survey data. This study
brings out 308 newly parameterised clusters. In a first of its kind, the LMC
clusters are classified into groups based on richness/mass as very poor, poor,
moderate and rich clusters, similar to the classification scheme of open
clusters in the Galaxy. A major cluster formation episode is found to happen at
125 +- 25 Myr in the inner LMC. The bar region of the LMC appears prominently
in the age range 60 - 250 Myr and is found to have a relatively higher
concentration of poor and moderate clusters. The eastern and the western ends
of the bar are found to form clusters initially, which later propagates to the
central part. We demonstrate that there is a significant difference in the
distribution of clusters as a function of mass, using a movie based on the
propagation (in space and time) of cluster formation in various groups. The
importance of including the low mass clusters in the cluster formation history
is demonstrated. The catalog with parameters, classification, and cleaned and
isochrone fitted CMDs of 1072 clusters, which are available as online material,
can be further used to understand the hierarchical formation of clusters in
selected regions of the LMC.Comment: 19 pages, 19figures, published in MNRAS on August 16, 2016
Supplementary material is available in the MNRAS websit
A multiscale model for dilute turbulent gas-particle flows based on the equilibration of energy concept
The objective of this study is to improve Eulerian-Eulerian models of particle-laden turbulent flow. We begin by understanding the behavior of two existing models—one proposed by Simonin [von Kármán Institute of Fluid Dynamics Lecture Series, 1996], and the other by Ahmadi [Int. J. Multiphase Flow16, 323 (1990)]—in the limiting case of statistically homogeneous particle-laden turbulent flow. The decay of particle-phase and fluid-phase turbulent kinetic energy (TKE) is compared with direct numerical simulation results. Even this simple flow poses a significant challenge to current models, which have difficulty reproducing important physical phenomena such as the variation of turbulent kinetic energy decay with increasing particle Stokes number. The model for the interphase TKE transfer time scale is identified as one source of this difficulty. A new model for the interphase transfer time scale is proposed that accounts for the interaction of particles with a range of fluid turbulence scales. A new multiphase turbulence model—the equilibration of energy model (EEM)—is proposed, which incorporates this multiscale interphase transfer time scale. The model for Reynolds stress in both fluid and particle phases is derived in this work. The new EEM model is validated in decaying homogeneous particle-laden turbulence, and in particle-laden homogeneous shear flow. The particle and fluid TKE evolution predicted by the EEM model correctly reproduce the trends with important nondimensional parameters, such as particle Stokes number
H I Kinematics of the Large Magellanic Cloud revisited : Evidence of possible infall and outflow
The neutral atomic Hydrogen (H I) kinematics of the Large Magellanic Cloud
(LMC) is revisited in light of two new proper motion estimates. We analysed the
intensity weighted H I velocity maps of the ATCA/Parkes and GASS data sets. We
corrected the line of sight velocity field for the systemic, transverse,
precession, and nutation motions of the disk using two recent proper motion
estimates, and estimated the kinematic parameters of the H I disk. The value of
position angle (PA) of kinematic major axis estimated using ATCA/Parkes data is
found to be similar to the recent estimate of the PA using stellar tracers. The
effect of precession and nutation in the estimation of PA is found to be
significant. Using ATCA/Parkes data, most of the H I gas in the LMC is found to
be located in the disk. We detected 12.1% of the data points as kinematic
outliers. We identified the well-known Arm E, Arm S, Arm W, Arm B and a new
stream, Outer Arm, as part of outlier components. The GASS data analysis brings
out the velocity details of the Magellanic Bridge (MB) and its connection to
the LMC disk. We find that the Arm B and the Outer Arm are connected to the MB.
We detect high velocity gas in the western disk of the LMC and the south-west
and southern parts of the MB. We proposed two models (in plane and out of
plane) to explain the outlier gas. We suggest that the Arm B could be an infall
feature, originating from the inner MB. The Arm E could be an outflow feature.
We suggest possible outflows from the western LMC disk and south and south
western MB, which could be due to ram pressure. The velocity pattern observed
in the MB suggests that it is being sheared. We suggest that the various
outliers identified in this study may be caused by a combination of tidal
effects and hydrodynamical effect due to the motion of the LMC in the Milky Way
(MW) halo.Comment: Accepted in A&A for publication. 15 pages, 14 figure
Secreted proteins of quiescent, serum-stimulated and over-confluent mouse embryo fibroblasts
Quiescent and proliferating cultures of Swiss mouse embryo fibroblasts were pulse labelled with [14C]-amino acids and the newly synthesized proteins that were secreted into the medium were resolved by electrophoresis on Polyacrylafde gradient gels. Conditioned media obtained from quiescent cultures that were stimulated to grow by the addition of 20% fetal calf serum showed the presence of two unique polypeptides of molecular weights 48000 and 26000. A polypeptide of molecular weight 45000 was present in increased amounts in serum-stimulated cells than in quiescent cells. This protein was also superinduced in quiescent cells by cycloheximide treatment. Mouse embryo fibroblasts grown under over-crowded conditions secreted two proteins of molecular weights 35000 and 11000. The 35 K polypeptide was shown to be related to the major excreted protein of transformed cells, since it was immunoprecipitated by an antiserum to major excreted protein. These results indicate that the 48 K and 26 K proteins may be proliferation specific proteins, while the 35 K protein present in the conditioned media of over-confluent cells may be a marker of morphological transformation
- …