| Program Number | Principal Investigator | Program Title |
|---|---|---|
| 11670 | Peter Garnavich, University of Notre Dame | The Host Environments of Type Ia Supernovae in the SDSS Survey |
| 11738 | George K. Miley, Universiteit Leiden | SPIDERWEBS AND FLIES: OBSERVING MASSIVE GALAXY FORMATION IN ACTION |
| 12023 | James C. Green, University of Colorado at Boulder | COS-GTO: Cold ISM |
| 12031 | James C. Green, University of Colorado at Boulder | COS-GTO: Sampling the Local ISM with hot white dwarfs - Part 2 |
| 12035 | James C. Green, University of Colorado at Boulder | COS-GTO: Activity of Solar Mass Stars from Cradle to Grave Part 2 |
| 12039 | James C. Green, University of Colorado at Boulder | COS-GTO: X-Ray Binaries |
| 12099 | Adam Riess, The Johns Hopkins University | Supernova Follow-up for MCT |
| 12102 | Marc Postman, Space Telescope Science Institute | Through a Lens, Darkly - New Constraints on the Fundamental Components of the Cosmos |
| 12103 | Marc Postman, Space Telescope Science Institute | Through a Lens, Darkly - New Constraints on the Fundamental Components of the Cosmos |
| 12106 | Julianne Dalcanton, University of Washington | A Panchromatic Hubble Andromeda Treasury - I |
| 12169 | Boris T. Gaensicke, The University of Warwick | The frequency and chemical composition of planetary debris discs around young white dwarfs |
| 12177 | Pieter van Dokkum, Yale University | 3D-HST: A Spectroscopic Galaxy Evolution Treasury |
| 12185 | Jenny E. Greene, University of Texas at Austin | The Hosts of Megamaser Disk Galaxies |
| 12188 | Jay B. Holberg, University of Arizona | Tests of Extreme Physics in Very Cool White Dwarfs |
| 12190 | Anton M. Koekemoer, Space Telescope Science Institute | WFC3/IR Spectroscopy of the Highest Redshift Black Hole Candidates |
| 12192 | James T. Lauroesch, University of Louisville Research Foundation, Inc. | A SNAPSHOT Survey of Interstellar Absorption Lines |
| 12206 | Mark S. Westmoquette, European Southern Observatory - Germany | Starburst-driven shocks and feedback in the near-IR at high resolution |
| 12239 | Gilda E. Ballester, University of Arizona | Springtime at Uranus: Upheaval in the Stratosphere? |
| 12254 | Adrienne Cool, San Francisco State University | Helium-core White Dwarfs and Cataclysmic Variables in NGC 6752: New Clues to the Dynamical Evolution of Globular Clusters |
| 12269 | Claudia Scarlata, University of Minnesota - Twin Cities | The escape of Lya photons in star-forming galaxies |
| 12272 | Christy A. Tremonti, University of Wisconsin - Madison | Testing Feedback: Morphologies of Extreme Post-starburst Galaxies |
| 12283 | Matthew A. Malkan, University of California - Los Angeles | WFC3 Infrared Spectroscopic Parallel Survey {WISP}: A Survey of Star Formation Across Cosmic Time |
| 12298 | Richard S. Ellis, California Institute of Technology | Towards a Physical Understanding of the Diversity of Type Ia Supernovae |
| 12307 | Andrew J. Levan, The University of Warwick | A public SNAPSHOT survey of gamma-ray burst host galaxies |
| 12320 | Brian Chaboyer, Dartmouth College | The Ages of Globular Clusters and the Population II Distance Scale |
| 12330 | J. Davy Kirkpatrick, California Institute of Technology | Spitzer Verification of the Coldest WISE?selected Brown Dwarfs |
| 12514 | Karl Stapelfeldt, NASA Goddard Space Flight Center | Imaging of Newly-identified Edge-on Protoplanetary Disks in Nearby Star-Forming Regions |
| 12549 | Thomas M. Brown, Space Telescope Science Institute | The Formation History of the Ultra-Faint Dwarf Galaxies |
| 12576 | Paul Kalas, University of California - Berkeley | Orbit determination for Fomalhaut b and the origin of the debris belt halo |
| 12686 | Stephen Bradley Cenko, University of California - Berkeley | Sw J2058+05: A Possible Second Relativistic Tidal Disruption Flare |
GO 11670: The Host Environments of Type Ia Supernovae in the SDSS Survey
SN 2007uy and 2008D in NGC 2770 |
Supernovae have long attracted the attention of both amateur and professional astronomers as a means of studying the violent eruption and death of massive stars and degenerates. However, in the last decade they have also acquired considerable importance as distance indicators, tracing the expansion of the universe to redshifts well beyond the reach of more conventional yardsticks, such as cepheids, and providing a key underpinning for the hypothesised existcen of dark energy. Understanding the supernovae themselves, and, in particular, their progenitors, is key to accurately interpreting their luminosities and distances. The present program aims to tackle that aspect of the problem by using ACS to obtain deep, high resolution images of galaxies that have harboured recent type Ia supernovae. The targets are all drawn from the Sloan Digital Sky Survey, which has uncovered more than than 500 type Ia supernovae,. The supernovae themselves are long gone from view, but the ACS data will be used to probe the stellar populations in the immediate vicinity of the explosion, and hence gain a better understanding of the likely progenitor. |
GO 12102: Through a Lens, Darkly - New Constraints on the Fundamental Components of the Cosmos
The ACS optical/far-red image of the galaxy cluster, Abell 2218, including an extensive number of lensed arcs |
The overwhelming majority of galaxies in the universe are found in clusters. As such, these systems offer an important means of tracing the development of large-scale structure through the history of the universe. Moreover, as intense concentrations of mass, galaxy clusters provide highly efficient gravitational lenses, capable of concentrating and magnifying light from background high redshift galaxies to allow detailed spectropic investigations of star formation in the early universe. Hubble imaging has already revealed lensed arcs and detailed sub-structure within a handful of rich clusters. At the same time, the lensing characteristics provide information on the mass distribution within the lensing cluster. The present program aims to capitalise fully on HST's imaging capabilities, utilising the refurbished Advanced Camera for Surveys and the newly-installed Wide-Field Camera 3 to obtain 17-colour imaging of 25 rich clusters. The data will be use to map the mass profiles of the clusters and probe the characteristics of the high-redshift lensed galaxies. Since ACS and WFC3 can be operated in parallel, the program will also use parallel imaging in offset fields to search for high-redshift supernovae. The present observations target the cluster MACS 2137-2353. |
GO 12320: The Ages of Globular Clusters and the Population II Distance Scale
Hubble Heritage image of the globular cluster, M15 |
Globular clusters are the oldest structures within the Milky Way that are directly accessible to observation. They are relatively simple systems, with relatively simple colour-magnitude diagrams (albeit with some complexities adduced from recent HST observations, see GO 11233 ). Matching those CMDs against theoretical models allows us to set constraints on the age of the oldest stars in the Galaxy, and hence on the age of the Milky Way and the epoch of galaxy formation. However, the accuracy of those age determinations rest crucially on the accuracy of the cluster distance determinations. The clusters themselves lie at distances of several kpc at best, and tens of kpc at worst; thus, direct trigonometric parallax measurements must await microacrsecond astrometric missions. The classical method of deriving distances is main sequence fitting - using nearby stars, with similar chemical abundances and accurate parallax measurements, to map out the main sequence in absolute units, and then scaling the cluster data to fit. The problem with this method is that metal-poor subdwarfs are rare, so even Hipparcos was only able to obtain accurate distances to a handful of stars. The present program aims to improve the distance measurements by using the Fine Guidance Sensors on HST to determine sub-millarcsecond trigonometric parallaxes to 9 subdwarfs, almost doubling the sample available for MS fitting. |
GO 12330: Spitzer Verification of the Coldest WISE-selected Brown Dwarfs
The stellar menagerie: Sun to Jupiter, via brown dwarfs |
Brown dwarfs are objects that form in the same manner as stars, by gravitational collapse within molecular clouds, but which do not accrete sufficient mass to raise the central temperature above ~2 million Kelvin and ignite hydrogen fusion. As a result, these objects, which have masses less than 0.075 MSun or ~75 M<\sub>Jup, lack a sustained source of energy, and they fade and cool on relatively short astronomical (albeit, long anthropological) timescales. Following their discovery over a decade ago, considerable observational and theoretical attention has focused on the evolution of their intrinsic properties, particularly the details of the atmospheric changes. At their formation, most brown dwarfs have temperatures of ~3,000 to 3,500K, comparable with early-type M dwarfs, but they rapidly cool, with the rate of cooling increasing with decreasing mass. As temperatures drop below ~2,000K, dust condenses within the atmosphere, molecular bands of titanium oxide and vanadium oxide disappear from the spectrum to be replaced by metal hydrides, and the objects are characterised as spectral type L. Below 1,300K, strong methane bands appear in the near-infrared, characteristics of spectral type T. At present, the coolest T dwarfs known have temperatures of ~650 to 700K. At lower temperatures, other species, notably ammonia, are expected to become prominent, and a number of efforts have been undertaken recently to find examples of these "Y" dwarfs. The search is complicated by the fact that such objects are extremely faint instrinsically, so only the nearest will be detectable. Identifying such ultra-ultracool dwarfs was a goal of the WISE satellite mission, which recently completed its all-sky survey. WISE has succeeded in identifying a number of extremely interesting sources, including at least 4 objects that have been confirmed as dwarfs with temperatures lower than 350K. These are among the first examples of Y dwarfs. The current program is combining WFC3-grism imaging with warm-Spitzer photometry to verify the nature of further candidates. |