* Astronomy

Computer simulations have reconstructed how dark matter clumped together with normal gas in the early universe to form small galaxies and how these small galaxies merged over billions of years to create huge star systems like the Milky Way.

The simulations raised one mystery, however. They showed that the density of dark matter should spike sharply at the centre of galaxies, while observations of the motions of stars reveal that the dark matter cores of galaxies today are much more puffed out, with densities that are constant over thousands of light years.

"We have known about this problem for more than 10 years" - Sergey Mashchenko from McMaster University in Hamilton, Ontario, Canada.

Astronomers have suggested several possible fixes for this anomaly. For instance, they thought that dark matter might puff outwards because some kind of exotic force between the particles - other than gravity - makes them collide and scatter off each other like snooker balls. Now Mashchenko and his colleagues have shown that the smoothing of the density of dark matter is down to the explosions of massive stars at the end of their lives. At their peak, these supernovae can outshine their host galaxies.
Mashchenko thought that shock waves from supernovae should churn up interstellar gas in a galaxy, and that the gravitational disturbances created by this sloshing gas should in turn smooth out the spike of dark matter at the centre. To test this, his team used a supercomputer to simulate the evolution of a small, primordial galaxy that started off with a central spike in the density of dark matter. Sure enough, just 80 supernovae explosions per million years - typical of values expected in dwarf galaxies today - were enough to smooth out the dark matter spike to match observations if they continued for at least 100 million years or so (Nature, vol 443, p 539).

The same model can also solve another conundrum. The cosmos has far fewer dwarf galaxies - which contain several billion stars compared with the hundreds of billions in larger galaxies - than cosmological simulations predict. In Mashchenko's simulations, because supernovae smoothed out the spike in dark matter density at the centre, dwarf galaxies were less tightly bound together by their own gravity. Any encounters with bigger galaxies would therefore have easily torn many dwarfs apart, and this may explain their paucity.

Source


Title: Cosmological puzzle resolved by stellar feedback in high redshift galaxies
Authors: Sergey Mashchenko, H. M. P. Couchman, James Wadsley

The standard cosmological model, now strongly constrained by direct observation at early epochs, is very successful in describing the structure of the evolved universe on large and intermediate scales. Unfortunately, serious contradictions remain on smaller, galactic scales. Among the major small-scale problems is a significant and persistent discrepancy between observations of nearby galaxies, which imply that galactic dark matter (DM) haloes have a density profile with a flat core, and the cosmological model, which predicts that the haloes should have divergent density (a cusp) at the centre. Here we use numerical N-body simulations to show that random bulk motions of gas in small primordial galaxies, of the magnitude expected in these systems, result in a flattening of the central DM cusp on short timescales (of order 10^8 years). Gas bulk motions in early galaxies are driven by supernova explosions which result from ongoing star formation. Our mechanism is general and would have operated in all star-forming galaxies at redshifts z>~ 10. Once removed, the cusp cannot be reintroduced during the subsequent mergers involved in the build-up of larger galaxies. As a consequence, in the present universe both small and large galaxies would have flat DM core density profiles, in agreement with observations.

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Title: Constraints on Sterile Neutrino Dark Matter
Authors: Kevork Abazajian, Savvas M. Koushiappas (Los Alamos National Laboratory)
(UPDATE)

Researchers present a comprehensive analysis of constraints on the sterile neutrino as a dark matter candidate. The minimal production scenario with a standard thermal history and negligible cosmological lepton number is in conflict with conservative radiative decay constraints from the cosmic X-ray background in combination with stringent small-scale structure limits from the Lyman-alpha forest. They show that entropy release through massive particle decay after production does not alleviate these constraints. They further show that radiative decay constraints from local group dwarf galaxies are subject to large uncertainties in the dark matter density profile of these systems. Within the strongest set of constraints, resonant production of cold sterile neutrino dark matter in non-zero lepton number cosmologies remains allowed.

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Title: Astrophysical Effects of Scalar Dark Matter Miniclusters
Authors: Kathryn M. Zurek, Craig J. Hogan, Thomas R. Quinn (UW, Physics and Astronomy Departments)

Researchers model the formation, evolution and astrophysical effects of dark compact Scalar Miniclusters ("ScaMs"). These objects arise when a scalar field, with an axion-like or Higgs-like potential, undergoes a second order phase transition below the QCD scale. Such a scalar field may couple too weakly to the standard model to be detectable directly through particle interactions, but may still be detectable by gravitational effects, such as lensing and baryon accretion by large, gravitationally bound miniclusters. The masses of these objects are shown to be constrained by the Ly alpha power spectrum to be less than 10^4 solar masses, but they may be as light as classical axion miniclusters, of the order of 10^-12 solar masses. The researchers simulate the formation and nonlinear gravitational collapse of these objects around matter-radiation equality using an N-body code, estimate their gravitational lensing properties, and assess the feasibility of studying them using current and future lensing experiments. Future MACHO-type variability surveys of many background sources can reveal either high-amplification, strong lensing events, or measure density profiles directly via weak-lensing variability, depending on ScaM parameters and survey depth. However, ScaMs are unlikely to be responsible for apparent MACHO events already detected in the Galactic halo.
A simple estimate is made of parameters that would give rise to early structure formation; in principle, early stellar collapse could be triggered by ScaMs as early as recombination, and significantly affect cosmic reionisation.

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     DARK MATTER is an invisible substante that has been here longer than any element known in the Universe. It is because it is the fabric foundation to what our Universe was formed on or in.  Reviewing aspects about the Multi-Verse Theory created by Stephen Hawkins. There are many Universe's. For this to be so. The Dark Matter fabric must be an infinite fabric substante created as a form of nothingness what entails the dark emptiness to everything in it.

     In Quanta Physics Theory developed by Rod Kawecki phd the Universe was formed through the accumulation of infinitesimal energies crushed by Black Holes and more so - even the Universe itself. So not only is the Universe spinning by perpetrual motion but as it does - the used up or recieved energy in a black hole or accumlated out of the Universe's massive perpetrual vortexium. The allusive energy changed by a black holes vortex is recieved at a distant area in the dark matter spectra where it accumulates and forms other Universe's. The theory also prospers that even other planets and stars are formed indivisually the same way. Formed at infinitesimal masses and accumulate other high frequency energy to grow into heavenly bodies throughout space.  The Universe never dies.