| Program Number | Principal Investigator | Program Title |
|---|---|---|
| 12116 | Julianne Dalcanton, University of Washington | A Panchromatic Hubble Andromeda and Triangulum Survey - Globular Cluster Sequence Calibrations |
| 12451 | Marc Postman, Space Telescope Science Institute | Through a Lens, Darkly - New Constraints on the Fundamental Components of the Cosmos |
| 12468 | Keith S. Noll, NASA Goddard Space Flight Center | How Fast Did Neptune Migrate? A Search for Cold Red Resonant Binaries |
| 12472 | Claus Leitherer, Space Telescope Science Institute | CCC - The Cosmic Carbon Conundrum |
| 12473 | David Kent Sing, University of Exeter | An Optical Transmission Spectral Survey of hot-Jupiter Exoplanetary Atmospheres |
| 12474 | Boris T. Gaensicke, The University of Warwick | The frequency and chemical composition of rocky planetary debris around young white dwarfs |
| 12479 | Esther M. Hu, University of Hawaii | Low-z Analogs of High Redshift Lyman Alpha Emitters |
| 12488 | Mattia Negrello, Open University | SNAPshot observations of gravitational lens systems discovered via wide-field Herschel imaging |
| 12511 | Travis Stuart Barman, Lowell Observatory | Determining the Atmospheric Properties of Directly Imaged Planets |
| 12533 | Crystal Martin, University of California - Santa Barbara | Escape of Lyman-Alpha Photons from Dusty Starbursts |
| 12535 | Susan D. Benecchi, Carnegie Institution of Washington | Orbital Refinement and Characterization of New Horizons KBO candidates |
| 12544 | Michael C. Cushing, University of Toledo | Confirming Ultra-cold {Teff < 500K} Brown Dwarf Suspects Identified with WISE |
| 12550 | Daniel Apai, University of Arizona | Physics and Chemistry of Condensate Clouds across the L/T Transition - A SNAP Spectral Mapping Survey |
| 12552 | Lisa Kewley, University of Hawaii | Shock Energy in Merging Systems: The Elephant in the Room. |
| 12554 | Timothy C. Beers, National Optical Astronomy Observatory, AURA | The Origins of Carbon-Enhanced Metal-Poor Stars |
| 12568 | Matthew A. Malkan, University of California - Los Angeles | WFC3 Infrared Spectroscopic Parallel Survey WISP: A Survey of Star Formation Across Cosmic Time |
| 12581 | Julia Christine Roman-Duval, Space Telescope Science Institute - ESA | A Direct CO/H2 Abundance Measurement in Diffuse and Translucent LMC and SMC Molecular Clouds |
| 12586 | Kailash C. Sahu, Space Telescope Science Institute | Detecting and Measuring the Masses of Isolated Black Holes and Neutron Stars through Astrometric Microlensing |
| 12604 | Andrew J. Fox, Space Telescope Science Institute - ESA | Ionization in the Magellanic Stream: A Case Study of Galactic Accretion |
| 12606 | Martin Barstow, University of Leicester | Verifying the White Dwarf Mass-Radius relation with Sirius B and other resolved Sirius-like systems |
| 12663 | Tuan Do, University of California - Irvine | Measuring the physical properties of the Milky Way nuclear star cluster with proper motions |
| 12751 | Craig Heinke, University of Alberta | The Spectral Energy Distribution of a Very Faint X-ray Transient |
| 12862 | Martha Boyer, Space Telescope Science Institute | Towards Identifying Carbon Stars Beyond the Local Group |
| 12942 | Eilat Glikman, Yale University | Testing the Merger Hypothesis for Black Hole/Galaxy Co-Evolution at z~2 |
| 12948 | Rollin Thomas, Lawrence Berkeley National Laboratory | Late Time STIS Spectroscopy of the Extremely Nearby Type Ia SN 2011fe |
| 12957 | Andreas H.W. Kuepper, Universitat Bonn, Argelander Institute for Astronomy | The Proper Motion of Palomar 5 and its Tidal Tails |
| 12983 | Ofer Yaron, Weizmann Institute of Science | The active pair-instability supernova PTF10nmn: late-time photometry, host properties and precise localization. |
| 13050 | Remco van den Bosch, Max-Planck-Institut fur Astronomie, Heidelberg | The Most Massive Black Holes in Small Galaxies |
| 13067 | Glenn Schneider, University of Arizona | The Jovian Transit of Venus - A 'Truth Test' for Atmospheric Characterization of Earth-Size Planets in Habitable Zones |
| 13118 | Michael C Nolan, Universities Space Research Association | Lightcurve observations of OSIRIS-REx Sample-Return Mission target 1999 RQ36 |
GO 12116: A Panchromatic Hubble Andromeda Treasury
M31: the Andromeda spiral galaxy |
M31, the Andromeda galaxy, is the nearest large spiral system to the Milky Way (d ~ 700 kpc), and, with the Milky Way, dominates the Local Group. The two galaxies are relatively similar, with M31 likely the larger system; thus, Andromeda provides the best opportunity for a comparative assessment of the structural properties of the Milky Way. Moreover, while M31 is (obviously) more distant, our external vantage point can provide crucial global information that complements the detailed data that we can acquire on individual members of the stellar populations of the Milky Way. With the advent on the ACS and, within the last 2 years, WFC3 on HST, it has become possible to resolve main sequence late-F and G dwarfs, permitting observations that extend to sub-solar masses in M31's halo and disk. Initially, most attention focused on the extended halo of M31 (eg the Cycle 15 program GO 10816 ), with deep imaging within a limited number of fields revealing the complex metallicity structure within that population. With the initiation of the present Multi-Cycle Treasury program, attention switches to the M31 disk. "PHAT" is conducting a multi-waveband survey of approximately one third of disk and bulge, focusing on the north-east quadrant. Observations extend over Cycles 19, 20 and 21, and will provide a thorough census of upper main-sequence stars, open clusters, associations and star forming regions, matching the stellar distribution against the dust and gas distribution. |
Preliminary orbital determination for the KBO WW31, based on C. Veillet's analysis of CFHT observations; the linked image shows the improved orbital derivation, following the addition of HST imaging |
The Kuiper Belt consists of icy planetoids that orbit the Sun within a broad band stretching from Neptune's orbit (~30 AU) to distance sof ~50 AU from the Sun (see David Jewitt's Kuiper Belt page for details). Over 500 KBOs (or trans-Neptunian objects, TNOs) are currently known out of a population of perhaps 70,000 objects with diameters exceeding 100 km. Approximately 2% of the known TNOs are binary (including Pluto, one of the largest known TNOs, regardless of whether one considers it a planet or not). TNOs are grouped within three broad classes: resonant objects, whose orbits are in mean motion resonance with Neptune, indicating capture; scattered objects, whose current orbits have evolved through gravitational interactions with Neptune or other giant planets; and classical TNOs, which are on low eccentricity orbits beyond Neptune, with no orbital resonance with any giant planet. The latter class are further sub-divided into "hot" and "cold" objects, depending on whether the orbits have high or low inclinations with respect to the ecliptic. Cold, classical TNOs show relatively uniform characteristics, including red colours, high albedos and an extremely high binary fraction (>30%). They are believed to have formed in situ, and were therefore in place to experience the range of gravitational interactions as the giant planets migrated to their present location. As that migration occurred, subsets are expected to have been trapped in transitory resonance orbits. The present proposal aims to use HST to complete a photometric survey of all known resonant TNOs, with the goal of identifying the proportion of cold classical TNOs that have been captured. The relative number of such objects can be used to constrain models for Neptune's orbital migration in the early Solar System. |
GO 12488: SNAPshot observations of gravitational lens systems discovered via wide-field Herschel imaging
ACS images of galaxy-galaxy Einstein ring lenses from the Sloan survey |
Gravitational lensing is a consequence the theory of general relativity. Its importance as an astrophysical tool first became apparent with the realisation (in 1979) that the quasar pair Q0957+561 actually comprised two lensed images of the same background quasar. In the succeeding years, lensing has been used primarily to probe the mass distribution of galaxy clusters, using theoretical models to analyse the arcs and arclets that are produced by strong lensing of background galaxies, and the large-scale mass distribution, through analysis of weak lensing effects on galaxy morphologies. Gravitational lensing can also be used to investigate the mass distribution of individual galaxies. Until recently, the most common background sources that were being detected and investigates were quasars. Galaxy-galaxy lenses, however, offer a distinct advantage, since the background source is extended, and therefore imposes a stronger constraints on the mass distribution of the lensing galaxy than a point-source QSO. HST has carried out a number of programs following up candidate lenses identified from the Sloan Digital Sky Survey (eg GO 10886 , GO 11289 , GO 12210 ). The present program is using WFCE on HST to obtain follow-up near-infrared (F110W) images of up to 200 candidate lenses selected from the Herschel Astrophysical Terahertz Large Area (H-ATLAS) and the Herschel Multi-tiered Extra-galactic (HerMES) surveys. The HST data will verify the nature of those candidates, and provide the angular resolution necessary to model the mass distribution. |
GO 12606: Verifying the White Dwarf Mass-Radius relation with Sirius B and other resolved Sirius-like systems
|
All single stars, and most binary stars, with masses less than ~7 solar masses are expected to end their lives as white dwarfs - extremely compact objects made of degenerate material, compressing ~0.3 to 1.4 solar masses of material into a sphere little larger in radius than the Earth. Theoretical evolutionary models predict a broad correlation between the mass of the main-sequence star and the mass of the remnant, although there is significant scatter in the observed initial-final mass relation. The models also predict that white dwarfs should follow mass-radius relations that depend on the composition, temperature and internal structure. The present program aims to test the predictions of those models by determining accurate masses and radii for a sample of white dwarfs in resolved binary systems. STIS spectra will be used to measure accurate Balmer line profiles for these hot degenerates, and those pofiles can be analysed to yield effective temperatuers and surface gravities. Moreover, the H-beta line profile has a sharp core that allows accurate measurement of the apparent radial velocity of the system. This measured velocity has two main components: the star's peculiar velocity relative to the Sun; and the gravitational redshift induced by the high field on a degenerate white dwarf. Sicne these stars are members of wide binary systems, observations of the main sequence companion can be used to determine the former quantity and hence allow emasurement of the latter, and set constraints on the white dwarf mass. |