27,348 research outputs found
Completely dark galaxies: their existence, properties, and strategies for finding them
There are a number of theoretical and observational hints that large numbers
of low-mass galaxies composed entirely of dark matter exist in the field. The
theoretical considerations follow from the prediction of cold dark matter
theory that there exist many low-mass galaxies for every massive one. The
observational considerations follow from the observed paucity of these low-mass
galaxies in the field but not in dense clusters of galaxies; this suggests that
the lack of small galaxies in the field is due to the inhibition of star
formation in the galaxies as opposed to the fact that their small dark matter
halos do not exist. In this work we outline the likely properties of low-mass
dark galaxies, and describe observational strategies for finding them, and
where in the sky to search. The results are presented as a function of the
global properties of dark matter, in particular the presence or absence of a
substantial baryonic dark matter component. If the dark matter is purely cold
and has a Navarro, Frenk and White density profile, directly detecting dark
galaxies will only be feasible with present technology if the galaxy has a
maximum velocity dispersion in excess of 70 km/s, in which case the dark
galaxies could strongly lens background objects. This is much higher than the
maximum velocity dispersions in most dwarf galaxies. If the dark matter in
galaxy halos has a baryonic component close to the cosmic ratio, the
possibility of directly detecting dark galaxies is much more realistic; the
optimal method of detection will depend on the nature of the dark matter. A
number of more indirect methods are also discussed.Comment: 12 pages, 4 figures, MNRAS in pres
Vortex-enhanced propulsion
It has been previously suggested that the generation of coherent vortical structures in the near-wake of a self-propelled vehicle can improve its propulsive efficiency by manipulating the local pressure field and entrainment kinematics. This paper investigates these unsteady mechanisms analytically and in experiments. A self-propelled underwater vehicle is designed with the capability to operate using either steady-jet propulsion or a pulsed-jet mode that features the roll-up of large-scale vortex rings in the near-wake. The flow field is characterized by using a combination of planar laser-induced fluorescence, laser Doppler velocimetry and digital particle-image velocimetry. These tools enable measurement of vortex dynamics and entrainment during propulsion. The concept of vortex added-mass is used to deduce the local pressure field at the jet exit as a function of the shape and motion of the forming vortex rings. The propulsive efficiency of the vehicle is computed with the aid of towing experiments to quantify hydrodynamic drag. Finally, the overall vehicle efficiency is determined by monitoring the electrical power consumed by the vehicle in steady and unsteady propulsion modes. This measurement identifies conditions under which the power required to create flow unsteadiness is offset by the improved vehicle efficiency. The experiments demonstrate that substantial increases in propulsive efficiency, over 50 % greater than the performance of the steady-jet mode, can be achieved by using vortex formation to manipulate the near-wake properties. At higher vehicle speeds, the enhanced performance is sufficient to offset the energy cost of generating flow unsteadiness. An analytical model explains this enhanced performance in terms of the vortex added-mass and entrainment. The results suggest a potential mechanism to further enhance the performance of existing engineered propulsion systems. In addition, the analytical methods described here can be extended to examine more complex propulsion systems such as those of swimming and flying animals, for whom vortex formation is inevitable
The mass loss process in dwarf galaxies from 3D hydrodynamical simulations: the role of dark matter and starbursts
Theoretical CDM cosmological models predict a much larger number of
low mass dark matter haloes than has been observed in the Local Group of
galaxies. One possible explanation is the increased difficulty of detecting
these haloes if most of the visible matter is lost at early evolutionary phases
through galactic winds. In this work we study the current models of triggering
galactic winds in dwarf spheroidal galaxies (dSph) from supernovae, and study,
based on 3D hydrodynamic numerical simulations, the correlation of the mass
loss rates and important physical parameters as the dark matter halo mass and
its radial profile, and the star formation rate. We find that the existence of
winds is ubiquitous, independent on the gravitational potential. Our
simulations revealed that the Rayleigh-Taylor Instability (RTI) may play a
major role on pushing matter out of these systems, even for very massive
haloes. The instability is responsible for 5 - 40% of the mass loss during the
early evolution of the galaxy, being less relevant at Myrs. There is
no significant difference in the mass loss rates obtained for the different
dark matter profiles studied (NFW and logarithmic). We have also found a
correlation between the mass loss rate and both the halo mass and the rate of
supernovae, as already reported in previous works. Besides, the epoch in which
most of the baryon galactic matter is removed from the galaxy varies depending
on the SN rate and gravitational potential. The later, combined to the
importance of the RTI in each model, may change our understanding about the
chemical evolution of dwarf galaxies, as well as in the heavy element
contamination of the intergalactic medium at high redshifts.Comment: MNRAS, accepte
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