* Astronomy

The ZEPLIN-II (ZonEd Proportional scintillation in LIquid Noble gases) dark matter experiment is a 30 kg two-phase xenon detector currently being commissioned at the Boulby Underground Laboratory, in the Boulby Mine, near Whitby, Yorkshire, by the UKDMC.
ZEPLIN-II consists of an approximate cylinder of liquid xenon of diameter 30 cm and height 13 cm. A 2 cm high gas phase is maintained above the liquid xenon level. An electric field strength of 1.8 kV/cm is applied across the liquid phase, and a higher electric field of 2.0 kV/cm is applied across the liquid-gas boundary.

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Title: First limits on WIMP nuclear recoil signals in ZEPLIN-II: a two phase xenon detector for dark matter detection
Authors: G. J. Alner, H. M. Ara´ujo, A. Bewick, C. Bungau, B. Camanzi, M. J. Carson R. J. Cashmore, H. Chagani, V. Chepel, D. Cline, D. Davidge, J. C. Davies, E. Daw, J. Dawson, T. Durkin, B. Edwards, T. Gamble, J. Gao, C. Ghag, A. S. Howard, W. G. Jones, M. Joshi, E. V. Korolkova, V. A. Kudryavtsev, T. Lawson, V. N. Lebedenko, J. D. Lewin, P. Lightfoot, A. Lindote, I. Liubarsky, M. I. Lopes, R. L¨uscher, P. Majewski, K Mavrokoridis, J. E. McMillan, B. Morgan, D. Muna, A. St.J. Murphy, F. Neves, G. G. Nicklin, W. Ooi, S. M. Paling, J. Pinto da Cunha, S. J. S. Plank, R. M. Preece, J. J. Quenby, M. Robinson, F. Sergiampietri, C. Silva, V. N. Solovov, N. J. T. Smith, P. F. Smith , N. J. C. Spooner, T. J. Sumner, C. Thorne, D. R. Tovey, E. Tziaferi, R. J. Walker, H. Wang, J. White & F. L. H. Wolfs
(Version V2)

Results are presented from the first underground data run of ZEPLIN-II, a 31 kg two phase xenon detector developed to observe nuclear recoils from hypothetical weakly interacting massive dark matter particles. Discrimination between nuclear recoils and background electron recoils is afforded by recording both the scintillation and ionisation signals generated within the liquid xenon, with the ratio of these signals being different for the two classes of event. This ratio is calibrated for different incident species using an AmBe neutron source and 60Co -ray sources. From our first 31 live days of running ZEPLIN-II, the total exposure following the application of fiducial and stability cuts was 225 kg×days. A background population of radon progeny events was observed in this run, arising from radon emission in the gas purification getters, due to radon daughter ion decays on the surfaces of the walls of the chamber. An acceptance window, defined by the neutron calibration data, of 50% nuclear recoil acceptance between 5 keVee and 20 keVee, had an observed count of 29 events, with a summed expectation of 28.6±4.3 -ray and radon progeny induced background events. These figures provide a 90% c.l. upper limit to the number of nuclear recoils of 10.4 events in this acceptance window, which converts to a WIMP-nucleon spin-independent cross-section with a minimum of 6.6×107 pb following the inclusion of an energy dependent, calibrated, efficiency. A second run is currently underway in which the radon progeny will be eliminated, thereby removing the background population, with a projected sensitivity of 2 × 107 pb for similar exposures as the first run.

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Our planet is constantly bombarded with cosmic rays. Most collide with atoms in our atmosphere, producing sprays of particles that fall to the ground, thousands striking each square meter every second. Cosmic rays with extremely high energies are infrequent, but their interactions in the atmosphere open a tiny but important window to ultra-high-energy physics a window that even the most advanced particle accelerators are incapable of achieving. Recently, three physicists took a peek in.
The interaction of a cosmic ray from outer space (typically a proton) with the atmosphere may result in the production of an exotic massive particle. This particle would be inside a shower of thousands of other particles. However, if it is long-lived, it will survive the shower without decaying and may be detected in a neutrino telescope or other detector. Here, the researchers focused on two theoretical exotic massive particles they believe are likely produced during these interactions: the gluino, a heavy twin of the gluon, and the weakly interacting massive particle (WIMP), which scientists believe could be a candidate for dark matter.

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Title: Do Mergers Spin up Dark Matter Halos?
Authors: Elena D'Onghia (1), Julio F. Navarro (2) ((1) University of Zurich, (2) University of Victoria)

We use a large cosmological N-body simulation to study the origin of possible correlations between the merging history and spin of cold dark matter halos. In particular, we examine claims that remnants of major mergers tend to have higher-than-average spins, and find that the effect is driven largely by unrelaxed systems: equilibrium dark matter halos show no significant correlation between spin and merger history. Out-of-equilibrium halos have, on average, higher spins than relaxed systems, suggesting that the virialisation process leads to a net decrease in the value of the spin parameter. We find that this decrease is driven by the internal redistribution of mass and angular momentum that occurs during virialisation, a process that is especially efficient during major mergers, when high angular momentum material is pushed beyond the virial radius of the remnant. Since such redistribution likely affects the angular momentum of baryons and dark matter unevenly, our findings question the common practice of identifying the specific angular momentum content of a halo with that of its embedded luminous component. Further work is needed to elucidate the true relation between the angular momentum content of baryons and dark matter in galaxy systems assembled hierarchically.

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Our Milky Way galaxy is heavier than it looks, and it's not too much ice cream, or cookies, that is responsible for the extra weight -- it's "dark matter."
Dark matter is one of the greatest mysteries in modern astronomy. Scientists use the term as an umbrella definition for all the invisible "heavy stuff" in the universe. Astronomers currently believe that there are two components to dark matter. One part of dark matter is made up of exotic materials, different from the ordinary particles that make up the familiar world around us. The other part consists of dark celestial bodies -- like planets, black holes, or failed stars -- which do not produce light or are too faint to detect from Earth.
Astronomers suspect that about most of our galaxy's and universe' weight comes from dark matter. For almost a century, they scoured our Milky Way galaxy for both exotic dark matter and dark celestial bodies in hopes of accounting for the missing weight.
Now, research is showing that NASA's Spitzer Space Telescope may be able to play an important role in identifying the "invisible" celestial bodies that are weighing our galaxy down.

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