| Program Number | Principal Investigator | Program Title |
|---|---|---|
| 14114 | Pieter van Dokkum, Yale University | A Wide-Field WFC3 Imaging Survey in the COSMOS Field |
| 14181 | S Thomas Megeath, University of Toledo | A Snapshot WFC3 IR Survey of Spitzer/Hershel-Identified Protostars in Nearby Molecular Clouds |
| 14216 | Robert P. Kirshner, Harvard University | RAISIN2: Tracers of cosmic expansion with SN IA in the IR |
| 14456 | Mark Brodwin, University of Missouri - Kansas City | Determining the Role of Merging in the Growth of the Galaxy Cluster Population in the Massive and Distant Clusters of WISE Survey |
| 14594 | Rich Bielby, Durham Univ. | QSAGE: QSO Sightline And Galaxy Evolution |
| 14606 | Brooke Devlin Simmons, University of California - San Diego | Secular Black Hole Growth and Feedback in Merger-Free Galaxies |
| 14608 | Nadia L Zakamska, The Johns Hopkins University | Host galaxies of high-redshift quasars with extreme outflows |
| 14609 | Tracy M Becker, Southwest Research Institute | Psyche's UV Reflectance Spectra: Exploring the origins of the largest exposed-core metallic asteroid |
| 14611 | Or Graur, Harvard University | Going gently into the night: constraining Type Ia supernova nucleosynthesis using late-time photometry |
| 14618 | Michael Shara, American Museum of Natural History | Ultraviolet Flashers in M87: Rapidly Recurring Novae as SNIa Progenitors |
| 14628 | Danielle Berg, University of Wisconsin - Milwaukee | The Evolution of C/O in Low Metallicity Dwarf Galaxies |
| 14633 | Kevin France, University of Colorado at Boulder | A SNAP UV Spectroscopic Study of Star-Planet Interactions |
| 14644 | Pieter van Dokkum, Yale University | Exploring the extremely low surface brightness sky: distances to 23 newly discovered objects in Dragonfly fields |
| 14675 | Julia Christine Roman-Duval, Space Telescope Science Institute - ESA | Metal Evolution and TrAnsport in the Large Magellanic Cloud (METAL): Probing Dust Evolution in Star Forming Galaxies |
| 14682 | Bjoern Benneke, California Institute of Technology | A Search for Methane, Ammonia, and Water on Two Habitable Zone Super-Earths |
| 14717 | Iair Arcavi, University of California - Santa Barbara | What is Enhancing the Tidal Disruption Rate of Stars in Post-Starburst Galaxies? |
| 14718 | George D. Becker, University of California - Riverside | The Metal-Enriched Environments of Galaxies Near Reionization |
| 14734 | Nitya Kallivayalil, The University of Virginia | Milky Way Cosmology: Laying the Foundation for Full 6-D Dynamical Mapping of the Nearby Universe |
| 14741 | Ignacio Negueruela, Universidad de Alicante, Dpto de Fisica | MY Cam: can homogeneous evolution produce gravitational-wave progenitors? |
| 14742 | Dieu D. Nguyen, University of Utah | Improving Central Black Hole Mass Measurements in Low Mass Early Type Galaxies |
| 14750 | Tao Wang, CEA/DSM/DAPNIA/Service d'Astrophysique | Exploring environmental effects on galaxy formation with WFC3 in the most distant cluster at z=2.506 |
| 14756 | Amy Simon, NASA Goddard Space Flight Center | Hubble 2020: Outer Planet Atmospheres Legacy (OPAL) Program |
| 14779 | Melissa Lynn Graham, University of Washington | A NUV Imaging Survey for Circumstellar Material in Type Ia Supernovae |
| 14789 | Thomas R. Ayres, University of Colorado at Boulder | Procyon: New Candidate for the Dynamo Clinical Trial |
| 14811 | Laurent Lamy, Observatoire de Paris - Section de Meudon | The Grand Finale : probing the origin of Saturn s aurorae with HST observations simultaneous to Cassini polar measurements |
| 14848 | Thomas R. Ayres, University of Colorado at Boulder | Cracking the Conundrum of F Supergiant Coronae |
| 14897 | Peter K. G. Williams, Harvard University | Quantifying the Impact of High-Energy Electrons on Low-Temperature Dwarfs |
GO 14114: A Wide-Field WFC3 Imaging Survey in the COSMOS Field
The full COSMOS field |
Hubble has made significant contributions in many science areas, but galaxy formation, assembly and evolution is a topic that has been transformed by the series of deep fields obtained over the past 20 years. The largest area survey to date was conducted in Cycles 12 & 13,when the Advanced Camera for Surveys was used to obtain single filter (F814) images of 2 square degrees in 640 orbits. The resultant dataset, the COSMOS survey, has been surveyed subsequently from both ground and space, with data spanning all wavelengths from X-ray through optical and infrared to the sub-millimetre and millimetre regimes. The HST data are important in providing data with exquisite angular resolution, as well as depth, providing important morphological information on galaxies in the field. Multi-wavelength data at the same resolution can provide important information on star formation history and evolution, and the spatial distribution of dust. Additional HST observations have been obtained for subsets of the field (eg the CANDELs field), but the large areal span has made full coverage overly expensive. That is, until a new observing technique was devised for HST that enables observations of multiple distinct fields in a single orbit. In standard the observing scenario, HST moves to a field, then acquries a guidestar to ensure acurate pointing and stability during the observation; each guide star acquisition takes 4-5 minutes, and HST is generally restricted to 2 pointings at most. In the new mode, HST makes the initial guide-star acquisition, but then offsets to new fields. The telescope drifts without a guide star, but this can be dealt with for near-infrared wavelength imaging; the HST detectors use multiple non-destructive reads, and the telescope drifts by a very limited amount in the time between reads. The net result is that it is possible to cover the COSMOS fields with H-band observations in 57 orbits, adding high angular resolution near-infrared data to compleemnt the ACS I-band data. |
GO 14633: A SNAP UV Spectroscopic Study of Star-Planet Interactions
SOHO image of an extremely strong solar flare |
Stellar activity, whether through flares and coronal mass ejections, has the potential to affect the ability of life to evolve and survive on otherwise habitable planets in stellar systems. High energy radiation can lead to significant mutations, and particle ejections can actually strip the atmospheres of unfortunate planets. Previous HST programs have focused on low mass M dwarfs, the most populous stars in the galaxy, and systems where the habitable zone lies close to the parent star, with a correspondingly higher vulnerability. Those observations suggest evidence for interactions between the stellar transition region and the planets, with a correlation between the presence of high temperature emission lines (N V, C IV, Si IV) and the planetary mass and orbit i.e. suggestive of planetary interactions driving conditions in the stellar corona. The present SNAP program expand obsevations to higher-mass K dwarfs and solar-type G dwarfs that are known to harbour exoplanets, searching for similar correlations. The Cosmic Origins Spectrograph will be used to obtain UV spectra (1150-1450 Angstroms), providing a broad sampling of the range of activity levels among these dwarfs. |
GO 14756: Hubble 2020: Outer Planet Atmospheres Legacy (OPAL) Program
Global map of Jupiter from OPAL's 2015 observations |
The gas giants and ice giants in the outer system have extended, dynamic gaseous atmospheres that show a range of phenomena reflecting the underlying composition and cloud structure. These are generally driven by solar insolation, with the consequence that the frequency, scale and range of features diminishes from Jupiter through saturn and Uranus to Neptune. Monitoring the changes in the wide variety of features in these atmospheres can provide insight into the velocity structrue and the energy sources. Hubble OPAL program was established in 2014 to support this type of monitoring campaign. The program targets all four outer planets for imaging with a wide range of broad and narrow-band filters on Wide Field Camera 3. The observations are spaced over two consecutive rotations, providing full longitudinal coverage for each planet. |
GO 14811: The Grand Finale : probing the origin of Saturn's aurorae with HST observations simultaneous to Cassini polar measurements
|
Planetary aurorae are stimulated by the influx of charged particles
from the Sun, which travel along magnetic field lines and funnel into the atmosphere near
the magnetic poles. Aurorae therefore require that a planet has both a substantial atmosphere and
a magnetic field. They are a common phenomenon on Earth, sometimes visible at magnetic latitudes
more than 40 degrees from the pole, and have also been seen on Jupiter, Saturn, Uranus
and Neptune. Saturn passed through its equinox in August 2009, and in the succeeding years the north pole has tilted
more and more towards the Sun. As a consequence, we now have an excellent view of the polar regions. Moreover,
the Cassini probe has moved into a polar orbit, that takes it regularly across the auroral regiosn.
The present program is using STIS to obtain time-tagged FUV images during those passages,
enabling a direct comparison of the large-scale structure with
|