Title: Impact of dark matter decays and annihilations on structure formation Authors: E. Ripamonti (1), M. Mapelli (2,3) ((1) Kapteyn Astronomical Institute, University of Groningen, (2) SISSA, Trieste, (3) University of Zürich)
We derived the influence of dark matter (DM) decays and annihilations on structure formation. The energy deposited by DM decays and annihilations into metal free halos both increases the gas temperature and enhances the formation of molecules. Within the primordial halos the temperature increase generally dominates over the molecular cooling, slightly delaying the collapse. In fact, the critical mass for collapse is generally higher than in the unperturbed case, when we consider the energy input from DM. In presence of DM decays and/or annihilations the fraction of baryons inside collapsed metal free halos should be slightly less (~0.4) than the expected cosmological value.
Title: Impact of dark matter on reionisation and heating Authors: M. Mapelli (1,2), E. Ripamonti (3) ((1) SISSA, (2) University of Zürich, (3) Kapteyn Astronomical Institute, University of Groningen)
We derived the evolution of the energy deposition in the intergalactic medium (IGM) by different decaying (or annihilating) dark matter (DM) candidates. Heavy annihilating DM particles (with mass larger than a few GeV) have no influence on reionisation and heating, even if we assume that all the energy emitted by annihilations is absorbed by the IGM. In the case of lighter particles, the impact on reionisation and heating depends on the efficiency of energy absorption by the IGM. We calculated the fraction of energy produced by decays and annihilations which is effectively absorbed by the IGM. We found that this fraction is generally high at very high redshift (>>100), but drops at more recent epochs.
Title: Determining the Nature of Dark Matter with Astrometry Authors: Louis E. Strigari, James S. Bullock, Manoj Kaplinghat
We show that measurements of stellar proper motions in dwarf spheroidal galaxies provide a powerful probe of the nature of dark matter. Allowing for general dark matter density profiles and stellar velocity anisotropy profiles, we show that the log-slope of the dark matter profile at about twice the stellar core (King) radius can be measured to within ± 0.2 when the proper motions of 200 stars are added to standard line-of-sight velocity dispersion data. This measurement of the log-slope provides a test of Cold and Warm Dark Matter theories at a sensitivity not possible with line-of-sight velocity dispersion measurements alone. The upcoming SIM PlanetQuest will have the sensitivity to obtain the required number of proper motions in Milky Way dwarf spheroidal galaxies.
Unfolding the Universes Dark Matter. For the first time ever, astronomers have created a three-dimensional map showing how dark matter is distributed across the Universe. This has been achieved by an international team of scientists using data from the NASA/ESA Hubble Space Telescope.
The behaviour of the Bullet cluster - the poster-child for the existence of dark matter - is provoking some cosmologists to propose that there might be a fifth fundamental force. Most physicists are confident that they have uncovered all the forces that affect ordinary matter: gravity, electromagnetism, and the strong and weak nuclear forces. If there was a fifth force that influenced only dark matter, however, it could easily be at work without us realising, says Glennys Farrar of New York University. She and her student Rachel Rosen believe they have found evidence for just such a force in the so-called Bullet cluster, which formed when a small galaxy cluster - the "bullet" - smashed into a larger cluster. The collision stripped the two clusters of 90 per cent of their normal matter, which ended up as a pool of gas in the middle.
Title: A Dark Matter Candidate from an Extra (Non-Universal) Dimension Authors: Marco Regis, Marco Serone, Piero Ullio
We show that a recently constructed five-dimensional (5D) model with gauge-Higgs unification and explicit Lorentz symmetry breaking in the bulk, provides a natural dark matter candidate. This is the lightest Kaluza-Klein particle odd under a certain discrete Z_2 symmetry, which has been introduced to improve the naturalness of the model, and resembles KK-parity but is less constraining. The dark matter candidate is the first KK mode of a 5D gauge field and electroweak bounds force its mass above the TeV scale. Its pair annihilation rate is too small to guarantee the correct relic abundance; however coannihilations with coloured particles greatly enhance the effective annihilation rate, leading to realistic relic densities.
The main annual conference of the American Astronomical Society began this morning, and it didn't take long to roll into action. In one of the very first sessions, Glennys Farrar of New York University described some startling hints of a fifth force of nature, on top of the Fab Four: electromagnetism, gravity, and the two forces that govern atomic nuclei. The idea of a fifth force has a checkered history, and experiments seem to rule it out. But those experiments apply only to ordinary matter. They say nothing about dark matter.
This composite shows three different components of the COSMOS survey: The normal matter (in red) determined mainly by the European Space Agency’s XMM/Newton telescope, the dark matter (in blue) and the stars and galaxies (in grey) observed in visible light with Hubble.
Expand (196kb, 1024 x 768) Expand (6,039kb, 4032 x 4032) Credit: NASA, ESA and R. Massey (California Institute of Technology)
Although 3D maps of ordinary matter have been produced before, the 3D dark matter map is a first. Watch an animation showing the dark matter map from different angles. Because it takes light more time to travel from farther away, the more distant slices of this 3D map represent earlier eras in the history of the universe. This allowed the team to trace changes in the distribution of dark matter over a period ranging from about 6.5 billion to 3.5 billion years ago.
This new map provides the best evidence to date that normal matter, largely in the form of galaxies, accumulates along the densest concentrations of dark matter. The map reveals a loose network of filaments that grew over time and intersect in massive structures at the locations of clusters of galaxies. The map stretches halfway back to the beginning of the universe and shows how dark matter has grown increasingly "clumpy" as it collapses under gravity.
Three-Dimensional Distribution of Dark Matter in the Universe - 6.5 Billion Years Ago
Expand (24kb, 560 x 543) Credit: NASA, ESA, and R. Massey (California Institute of Technology)
The dark matter map was constructed by measuring the shapes of half a million faraway galaxies. To reach Hubble, the light of the galaxies travelled through intervening dark matter. The dark matter deflected the light slightly as it travelled through space. Researchers used the observed, subtle distortion of the galaxies' shapes to reconstruct the distribution of intervening mass along Hubble's line of sight, a method called "weak gravitational lensing."