| Program Number | Principal Investigator | Program Title |
|---|---|---|
| 13375 | Dougal Mackey, Australian National University | Deep photometry of two accreted families of globular clusters in the remote M31 halo |
| 13450 | Douglas R. Gies, Georgia State University Research Foundation | Separating the Spectral Components of the Massive Triple Star System Delta Orionis |
| 13467 | Jacob L. Bean, University of Chicago | Follow The Water: The Ultimate WFC3 Exoplanet Atmosphere Survey |
| 13482 | Britt Lundgren, University of Wisconsin - Madison | The Evolving Gas Content of Galaxy Halos: A Complete Census of MgII Absorption Line Host Galaxies at 0.7 < z < 2.5 |
| 13504 | Jennifer Lotz, Space Telescope Science Institute | HST Frontier Fields - Observations of MACSJ1149.5+2223 |
| 13646 | Ryan Foley, University of Illinois at Urbana - Champaign | Understanding the Progenitor Systems, Explosion Mechanisms, and Cosmological Utility of Type Ia Supernovae |
| 13652 | Boris T. Gaensicke, The University of Warwick | The frequency and chemical composition of rocky planetary debris around young white dwarfs: Plugging the last gaps |
| 13671 | Harald Ebeling, University of Hawaii | Beyond MACS: A Snapshot Survey of the Most Massive Clusters of Galaxies at z>0.5 |
| 13677 | Saul Perlmutter, University of California - Berkeley | See Change: Testing time-varying dark energy with z>1 supernovae and their massive cluster hosts |
| 13679 | Lorenz Roth, Royal Institute of Technology | Europa's Water Vapor Plumes: Systematically Constraining their Abundance and Variability |
| 13697 | Vianney Lebouteiller, CEA/DSM/Irfu/Service d'Astrophysique - Laboratoire AIM | Does star formation proceed differently in metal-poor galaxies? |
| 13703 | Lida Oskinova, Universitat Potsdam | The donor star winds in High-Mass X-ray Binaries |
| 13705 | Jennifer Patience, Arizona State University | Brown dwarf Atmosphere Monitoring (BAM): Characterizing the Coolest Atmosphere |
| 13706 | Joshua E. G. Peek, Columbia University in the City of New York | Galactic Accretion Unveiled: A Unique Opportunity with COS and M33 |
| 13724 | Todd J. Henry, Georgia State University Research Foundation | Pinpointing the Characteristics of Stars and Not Stars --- VERSION 2014.1021 |
| 13741 | Thaisa Storchi-Bergmann, Universidade Federal do Rio Grande do Sul | Constraining the structure of the Narrow-Line Region of nearby QSO2s |
| 13750 | John M. Cannon, Macalester College | Fundamental Parameters of the SHIELD II Galaxies |
| 13754 | Jeremy J. Drake, Smithsonian Institution Astrophysical Observatory | The first mass and angular momentum loss measurements for a CV-like binary |
| 13755 | Jenny E. Greene, Princeton University | The Hosts of Megamaser Disk Galaxies (II) |
| 13760 | Derck L. Massa, Space Science Institute | Filling the gap --near UV, optical and near IR extinction |
| 13761 | Stephan Robert McCandliss, The Johns Hopkins University | High efficiency SNAP survey for Lyman alpha emitters at low redshift |
| 13763 | S. Thomas Megeath, University of Toledo | WFC3 Spectroscopy of Faint Young Companions to Orion Young Stellar Objects |
| 13766 | Peter Christian Schneider, Universitat Hamburg, Hamburger Sternwarte | The nature of stationary components in jets from young stellar objects |
| 13767 | Michele Trenti, University of Cambridge | Bright Galaxies at Hubble's Detection Frontier: The redshift z~9-10 BoRG pure-parallel survey |
| 13776 | Michael D. Gregg, University of California - Davis | Completing The Next Generation Spectral Library |
| 13779 | Sangeeta Malhotra, Arizona State University | The Faint Infrared Grism Survey (FIGS) |
| 13813 | Sean A. Farrell, University of Sydney | Mapping the Broad-band Spectrum of a New Candidate Intermediate Mass Black Hole |
| 13844 | Bret Lehmer, The Johns Hopkins University | Unveiling the Black Hole Growth Mechanisms in the Protocluster Environment at z ~ 3 |
| 14041 | Patrick Kelly, University of California - Berkeley | Classifying and Following a Strongly Lensed Likely Supernova with Multiple Images |
GO 13467: Follow The Water: The Ultimate WFC3 Exoplanet Atmosphere Survey
Probing the atmosphere of a transiting exoplanet |
The first exoplanet, 51 Peg b, was discovered in 1995 through high-precision radial velocity measurements. 51 Pegb was followed by a trickle, and then a flood of other discoveries, as astronomers realised that there were other solar systems radically different from our own, where "hot jupiters" led to short-period, high-amplitude velocity variations. Then, in 1999, came the inevitable discovery that one of those hot jupiters. HD 209458b, was in an orbit aligned with our line of sight to the star, resulting in transits. Since that date, the number of known transiting exoplanet systems has grown to more than 400 in over 300 planetary systems, with the overwhelming majority identified by the Kepler satellite, which has also contributed close to 3,000 additional (very strong) candidates. As these observations have accumulated,the broad diversity of exoplanet systems has become increasingly apparent. Transiting systems are invaluable, since they provide not only unambiguous measurements of mass and diameter, but also an opportunity to probe the atmospheric structure by differencing spectra taken during and between primary secondary transit. Such observations are best done from space: indeed, while high-precision ground-based observations have succeeded in constraining atmospheric properties in a few systems, the only successful detections of atmospheric features to date have been with HST and Spitzer. HST capabilities have been enhanced in the last few years with addition of spatial scanning, moving the target star over the chip in a controlled fashion during an observation. This allows observers to accumulate images or spectra of substantially higher signal-to-noise, a crucial advantage if one is looking for flux differences of less than 1 part in 104. Past programs have accumulated observations of over a dozen exoplanets, using STIS at optical wavelengths and WFC3 in the near-infrared. The present program targets eight exoplanet systems with a diverse range of properties: HD 209458b,GL 3470b, HAT-P-26b, WASP-12b, WASP-18b, WASP-43b, WASP-80b and WASP-19b. The WFC3-IR G141 grism will be used to search for the characteristic near-infrared spectral features due to water in the amospheres of these exoplanets. |
GO 13679: Europa's Water Vapor Plumes: Systematically Constraining their Abundance and Variability
The HST imaging of a potential water plume around Europa's south pole superimposed on an image of the satellite |
Europa is the smallest, and the most intriguing, of the four Galilean satellites of Jupiter. With a diameter of 3139 km, Europa is almost twice the size of Earth's moon and significantly larger than Mercury. In 1957, Gerard Kuiper commented that both infrared spectroscopy and the optical colours and albedo suggested that Jovian satellite II (Europa) is covered "by H2O snow". Images taken by the Voyager space probes in the late 1970s (see left) reveal a smooth surface, with only a handful of craters larger than a few kilometres. These features are consistent with a relatively young, icy surface. Subsequent detailed investigations by the Galileo satellite strongly suggest that a substantial body of liquid water, heated by tidal friction, underlies a 5 to 50 km thick icy crust. The presence of this subterranean (subglacial?) ocean clearly makes Europa one of the two most interesting astrobiology targets in the Solar System. Most recently, analysis of observations taken by the Space Telescope imaging Spectrograph (STIS) on Hubble indicated the presence of an extended cloud of Lyman-alpha emission near the polar regions while Europa was furthest in its orbit from Jupiter, strongly suggesting that Europa's oceans may be vaporising into space.Follow-up observations on two further occasions earlier in 2014 failed to detect any emission, suggesting that the emission is either sporadic or periodic; in the latter case, the emission might be related to the location of Europa within its orbit and the consequent tidal strain imposed by Jupiter. The present program aims to address this question through a methodical series of observatons designed to image Europa at a progressive series of orbital locations. The program uses STIS to search for H and O auroral emissions at UV wavelengths\ and will aim to map the distribution of emission at different phases of the Europan orbit.. |
GO 13767: Bright Galaxies at Hubble's Detection Frontier: The redshift z~9-10 BoRG pure-parallel survey
 The ACS optical/far-red image of the Hubble Ultra Deep Field |
Galaxy evolution in the early Universe is a discipline of astronomy that has been transformed by observations with the Hubble Space Telescope. The original Hubble Deep Field, the product of 10 days observation in December 1995 of a single pointing of Wide Field Planetary Camera 2, demonstrated conclusively that galaxy formation was a far from passive process. The images revealed numerous blue disturbed and irregular systems, characteristic of star formation in galaxy collisions and mergers. Building on this initial progam, the Hubble Deep Field South (HDFS) provided matching data for a second southern field, allowing a first assessment of likely effects due to field to field cosmic variance, and the Hubble Ultra-Deep Field (UDF) probed to even fainter magitude with the Advanced Camera for Surveys (ACS). The highest redshift objects found in the UDF have redshifts approaching z~7. Pushing to larger distances, and greater ages, demands observatons at near-infrared wavelengths, as the characteristics signatures of star formation are driven further redward in the spectrum. Wide Field Camera 3, installed in Servicing Mission 4, is well suited to these observations, and a number of programs are in place in Cycle 17 that address these issues. Indeed, WFC3 is employed in pure parallel mode by several programs. These take advantage of other science programs, usually with COS, that involve 2-5 orbit pointings on sources at high galactic latitude. The WFC3 pointing is unplanned, since it depends on the orientation adopted for the prime observations, but 2-5 orbits of IR imaging can reach galaxies at redshifts exceeding z=7 (potentially even z~8) in high latitude fields. The present program builds on similar programs in Cycles 17 and 19, and aims to detect the brightest galaxies at z~9, within 600 Myrs of the Big Bang. |
GO 14041: Classifying and Following a Strongly Lensed Likely Supernova with Multiple Images
Finding chart for the multiply imaged supernova, SN Refsdal, discovered in November 2014 in cluster MACJ1149 |
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. Hubble is currently undertaking deep imaging observations of up to 6 galaxy clusters as part of the Frontier Fields Director's Time program (GO 13495/13496). Those observations have provided a basis for several synergistic programs. The present program is using the Frontier Field observations to search for supernovae at high redshifts, z> 1.5, aiming to set further constraints on dark energy and probing the frequency of supernovae as a function of redshift, the delay time and hence the likely progenitors. Recent observations of the fourth cluster, MACSJ1149.5+2223, resulted in the detection of a particularly unusual object - multiple lensed images of a supernova in a redshift z=1.49 galaxy that is itself multiply lensed. Each of those images results from light following a different path due to the gravitational potential of the foreground cluster and galaxies. Follow-up observations are being obtained to monitor the light-curves of each component, hence determining the time-delay for each light path. Those measured delays can be matched against the predictions of gravitational lensing models. Moreover, since the galaxy itself has multiple images it is possible that future observations may detect images of the supernova in other components. An extensive imaging program is underway, monitoring the detailed light curve of the object. The present DD program is using the WFC3 G141 grism to obtain spectra of the images, with the goal of determining unequiviocally the type of supernova. If the object is a Type Ia, then the observed magnitude can be matched against the expected intrinsic luminosity as a function of time, providing direct measurement of the lensing amplification at specific points within the system.The timing observations will also provide direct measurements of the Hubble constant at this epoch. |