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: http://www.stsci.edu/~inr/thisweek1/thisweek295.html
Дата изменения: Mon Oct 22 20:48:30 2007 Дата индексирования: Tue Oct 2 14:18:41 2012 Кодировка: Поисковые слова: star trail |
| Program Number | Principal Investigator | Program Title | Links |
| 10795 | Timothy Heckman, The Johns Hopkins University | The Largest Galaxies in the Local Universe: New Light on Disk Galaxy Formation? | Abstract |
| 10798 | Leon Koopmans, Kapteyn Astronomical Institute | Dark Halos and Substructure from Arcs & Einstein Rings | Abstract |
| 11082 | Christopher Conselice, Univ. of Nottingham | NICMOS Imaging of GOODS: Probing the Evolution of the Earliest Massive Galaxies, Galaxies Beyond Reionization, and the High Redshift Obscured Universe | Abstract |
| 11126 | Kristin Chiboucas, University of Hawaii | Resolving the Smallest Galaxies | Abstract |
| 11128 | David Bradley Fisher, University of Texas at Austin | Time Scales Of Bulge Formation In Nearby Galaxies | Abstract |
| 11130 | Luis Ho, Carnegie Institution of Washington | AGNs with Intermediate-mass Black Holes: Testing the Black Hole-Bulge Paradigm, Part II | Abstract |
| 11169 | Michael E. Brown, California Institute of Technology | Collisions in the Kuiper belt | Abstract |
| 11170 | John T. Clarke, Boston University | UV Imaging of the Martian Corona and the Escape of Hydrogen | Abstract |
| 11178 | William M. Grundy, Lowell Observatory | Probing Solar System History with Orbits, Masses, and Colors of Transneptunian Binaries | Abstract |
| 11194 | Douglas Clowe , Ohio University | Beyond the Bullet: Direct Detection of Dark Matter in Merging Galaxy Clusters | Abstract |
| 11197 | Peter Garnavich, University of Notre Dame | Sweeping Away the Dust: Reliable Dark Energy with an Infrared Hubble Diagram | Abstract |
| 11203 | Kevin Luhman, The Pennsylvania State University | A Search for Circumstellar Disks and Planetary-Mass Companions around Brown Dwarfs in Taurus | Abstract |
| 11211 | George Fritz Benedict, University of Texas at Austin | An Astrometric Calibration of Population II Distance Indicators | Abstract |
| 11212 | Douglas R. Gies, Georgia State University Research Foundation | Filling the Period Gap for Massive Binaries | Abstract |
| 11229 | Margaret Meixner, Space Telescope Science Institute | SEEDS: The Search for Evolution of Emission from Dust in Supernovae with HST and Spitzer | Abstract |
| 11289 | Jean-Paul Kneib, Laboratoire d'Astronomie Spatiale | SL2S: The Strong Lensing Legacy Survey | Abstract |
| 11296 | Howard E. Bond, Space Telescope Science Institute | HST Observations of Astrophysically Important Visual Binaries | Abstract |
GO 11170: UV Imaging of the Martian Corona and the Escape of Hydrogen
The Martian atmosphere
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Mars possesses a very thin atmosphere that consists mainly of carbon dioxide (~95%).
The other major constituents are nitrogen (~2.7%) and argon (~1.6%), with oxygen and
water vapour contributing trace amounts. The surface pressure is only 7 millibars, or less
than 1% of Earth's current atmosphere. This tenuous body is the remnant of a much denser
envelope that was gradually dispersed primarily through interactions with solar radiation
and particles in the solar wind. Those interactions still take place, generating an
extended corona of very low density gas, including hydrogen from dissociated water vapour.
The aim of the present program is to use the Solar Blind Channel on the ACS to
search for coronal Lyman alpha emission. The observatons are co-ordinated with |
GO 11194: Beyond the Bullet: Direct Detection of Dark Matter in Merging Galaxy Clusters
1E0657-56, the original Bullet cluster: Chandra observations of the X-ray emission are shown in red; the inferred dark matter distribution is shown in blue.
|
The Bullet cluster, 1E0657-56, was publicised in a press release in August 2006, during the Prague IAU meeting. Originally identified through the strong X-ray emission, the "cluster" actually consists of two galaxy clusters that are undergoing a collision. The X-ray emission, generated by hot gas, is offset from the galaxian cluster members - as expected, given that the intercluster baryonic material in the two clusters will interact dissipationally during the collision. Crucially, the dark matter distributions, as determined from weak lensing, remain centred on the galaxies. 1E0657-56, however, is only one cluster, and there is the possibility, however remote, that a conspiracy of circumstances and chance alignments has given rise to the observed characteristics. The present program aims to set that concern at rest through WFPC2 observatons of a second cluster, Abell 1758. |
GO 11229: The Search for Evolution of Emission from Dust in Supernovae with HST and Spitzer
Supernova 1987A in the LMC, an HST image acquired by WFPC2 in 1998 |
Type II supernovae are produced by core collapse in stars exceeding ~7 solar masses. These massive stars support a complex series of nuclear reactions on the main sequence, ranging from hydrogen fusiuon near the surface to silicon reactions that build up the iron core. This produces an internal onion-ring structure, with a wide range of chemical species that are blasted into the interstellar medium when the core exceeds the Chandrasekhar mass an implodes. These supernovae are widely hypothesised as a potent source of interstellar dust, with the material condesning within the cooling ejecta. However, observations have so far provided only lukewarm support for these theoretical expectations. This proposal combines optical and near-infrared HST observations of recent type II supernovae, using WFPC2 and NICMOS, respectively, with mid-infrared imaging with IRAC and MIPS on Spitzer. The aim is to use the multiwavelength imaging to probe the evolution of the dust content in the surrounding ejecta. NICMOS observations of SN2006BC in NGC 2397. |
GO 11203: A Search for Circumstellar Disks and Planetary-Mass Companions around Brown Dwarfs in Taurus
Stars and brown dwarfs forming from a collapsing molecular cloud (from one of the simulations
constructed by Matthew Bate)
|
Understanding how and why brown dwarfs form is a key part of the larger issue of understanding the overall star formation process. The end points are obvious: we start with a large cloud of molecular gas, a giant molecular cloud (GMC) typically encompassing 105< to 106 solar masses of material, and end up with a collection from a few hundred to several thousand discrete objects, with masses that can range from (perhaps) a few Jupiter masses to 100 solar masses. The detail covered by the intermediate stages is less well understood. Brown dwarfs pose a particular problem because their final masses are so much smaller than the Jeans mass for a typical GMC. One potential mechanism, originating primarily with Matthew Bate and Ian Bonnell, envisages brown dwarfs truly as failed stars - objects that were ejected from star clusters before they could accrete sufficient material to reach stellar masses. That model makes several predictions, including a low binary fraction (<5%) and little in the way of circumstellar material. The present program aims to test the latter prediction by surveying very low-mass stars and brown dwarfs in the Taurus star-forming region, using WFPC2 far-red imaging to search for evidence for circumstellar disks. |