* Astronomy

Title: Search for axion-like particles using a variable baseline photon regeneration technique
Authors: A.S. Chou, W. Wester, A. Baumbaugh, H.R. Gustafson, Y. Irizarry-Valle, P.O. Mazur, J.H. Steffen, R. Tomlin, X. Yang, J. Yoo

We report the first results of the GammeV experiment, a search for milli-eV mass particles with axion-like couplings to two photons. The search is performed using a "light shining through a wall" technique where incident photons oscillate into new weakly interacting particles that are able to pass through the wall and subsequently regenerate back into detectable photons. The oscillation baseline of the apparatus is continuously variable, thus allowing probes of different values of particle mass. We find no excess of events above background and are able to constrain the two-photon couplings of possible new scalar (pseudoscalar) particles to be less than 3.2 x 10^{-7} {GeV}^{-1} (3.2 x 10^{-7} {GeV}^{-1}) in the limit of massless particles.

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New calculations show at least 2.1 million-billion years must pass for half of the invisible stuff to decay, if it does at all.
While all this theoretical thinking seems awfully abstract, it represents yet another effort to pin down what the heck dark matter might really be.
Scientists proposed the half-life about 150,000 times longer than the current age of the universe after looking at X-rays from the Bullet Cluster, a cosmic collision of galaxies thought to harbour two massive globs of dark matter.
If dark matter can slowly decay, it can also emit radiation, albeit at nearly undetectable levels. The proposed ultra-wimpy signal might help explain why it's practically invisible to our scientific instruments.

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Title: Dilaton and off-shell (non-critical string) effects in Boltzmann equation for species abundances
Authors: AB Lahanas, NE Mavromatos and DV Nanopoulos

In this work we derive the modifications to the Boltzmann equation governing the cosmic evolution of relic abundances induced by dilaton dissipative-source and non-critical-string terms in dilaton-driven non-equilibrium string Cosmologies. We also discuss briefly the most important phenomenological consequences, including modifications of the constraints on the available parameter space of cosmologically appealing particle physics models, imposed by recent precision data of astrophysical measurements.

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Astronomers using the Hubble Space Telescope have discovered a ghostly ring of dark matter that formed during a titanic collision between two massive galaxy clusters. Because ordinary matter in the cluster shows no evidence of such a ring, this discovery is among the strongest evidence yet for non-baryonic dark matter.
Clusters of galaxies are the largest gravitationally bound structures in the universe. They typically contain hundreds or thousands of galaxies, forming at the knots of the filamentary sponge-like distribution of matter on very large scales. Numerical simulations show how the accretion of matter from the filaments to the knots make galaxy clusters grow in size. This one-dimensional accretion (along a filament) results in frequent, near head-on collisions among clusters or groups of galaxies, whereas interactions between individual galaxies usually occur only when there is significant rotation.

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Title: Searching for Decaying Axionlike Dark Matter from Clusters of Galaxies
Authors: Signe Riemer-Sørensen, Konstantin Zioutas, Steen H. Hansen, Kristian Pedersen, Håkon Dahle, and Anastasios Liolios

We constrain the lifetime of radiatively decaying dark matter in clusters of galaxies inspired by generic Kaluza-Klein axions, which have been invoked as a possible explanation for the solar coronal x-ray emission. These particles can be produced inside stars and remain confined by the gravitational potential of clusters. By analysing x-ray observations of merging clusters, where gravitational lensing observations have identified massive, baryon poor structures, we derive the first cosmological lifetime constraint on this kind of particles of tau >~10²³ sec.

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