| Program Number | Principal Investigator | Program Title |
|---|---|---|
| 13302 | J. Michael Shull, University of Colorado at Boulder | COS Spectra of High-Redshift AGN: Probing Deep into the Rest-Frame Ionizing Continuum and Broad Emission Lines |
| 13317 | Dan Coe, Space Telescope Science Institute - ESA | Infrared Grism Confirmation of a Strongly Lensed z ~ 11 Candidate: MACS0647-JD |
| 13319 | Alexandros Gianninas, The University of Oklahoma | COS Spectroscopy of Pulsating, Metal-Rich, Extremely Low Mass White Dwarfs |
| 13450 | Douglas R. Gies, Georgia State University Research Foundation | Separating the Spectral Components of the Massive Triple Star System Delta Orionis |
| 13451 | Frederick Hamann, University of Florida | A Study of PG Quasar-Driven Outflows with COS |
| 13472 | Wendy L. Freedman, University of Chicago | The Hubble Constant to 1%? STAGE 4: Calibrating the RR Lyrae PL relation at H-Band using HST and Gaia Parallax Stars |
| 13517 | Matthew A. Malkan, University of California - Los Angeles | WFC3 Infrared Spectroscopic Parallel Survey WISP: A Survey of Star Formation Across Cosmic Time |
| 13650 | Kevin France, University of Colorado at Boulder | The MUSCLES Treasury Survey: Measurements of the Ultraviolet Spectral Characteristics of Low-mass Exoplanetary Systems |
| 13654 | Matthew Hayes, Stockholm University | Ultraviolet Spectroscopy of the Extended Lyman Alpha Reference Sample |
| 13656 | Matthew Hayes, Stockholm University | Unveiling the Dark Baryons: The First Imaging of Circumgalactic OVI in Emission |
| 13678 | Adam Riess, The Johns Hopkins University | The Fifth and Final Epoch |
| 13686 | Adam Riess, The Johns Hopkins University | The Longest Period Cepheids, a bridge to the Hubble Constant |
| 13690 | Tanio Diaz-Santos, California Institute of Technology | Tracking the Obscured Star Formation Along the Complete Evolutionary Merger Sequence of LIRGs |
| 13695 | Benne W. Holwerda, Sterrewacht Leiden | STarlight Absorption Reduction through a Survey of Multiple Occulting Galaxies (STARSMOG) |
| 13696 | Benne W. Holwerda, Sterrewacht Leiden | The Anemic Stellar Halo of M101 |
| 13750 | John M. Cannon, Macalester College | Fundamental Parameters of the SHIELD II Galaxies |
| 13755 | Jenny E. Greene, Princeton University | The Hosts of Megamaser Disk Galaxies (II) |
| 13758 | Andreas Koch, Landessternwarte Heidelberg | The Age-Metallicity relationship of the Galactic Bulge via Stromgren Photometry |
| 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 |
| 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 |
| 13777 | Michael D. Gregg, University of California - Davis | Morphological Transformation in the Coma Cluster |
| 13790 | Steven A. Rodney, The Johns Hopkins University | Frontier Field Supernova Search |
| 13829 | William B. Sparks, Space Telescope Science Institute | The ice plumes of Europa |
| 13830 | Nial R. Tanvir, University of Leicester | r-process kilonova emission accompanying short-duration GRBs |
| 13871 | Pascal Oesch, Yale University | A Spectroscopic Redshift for the Most Luminous Galaxy Candidate at z~10 |
| 13872 | Pascal Oesch, Yale University | The GOODS UV Legacy Fields: A Full Census of Faint Star-Forming Galaxies at z~0.5-2 |
| 13928 | Adam Riess, The Johns Hopkins University | HST and Gaia, Light and Distance |
| 14040 | David Jewitt, University of California - Los Angeles | Unique Hubble Investigation of a Newly Discovered Main Belt Comet |
GO 13928: HST and Gaia, Light and Distance
HST WFPC2 image of NGC 4639, one of the Cepheid-rich spiral galaxies used to calibrate SNe Ia |
The cosmic distance scale and dark energy are two key issues in modern astrophysics, and HST has played a vital role in probing both. On the one hand, HST has been involved in cosmic distance measurements since its inception, largely through the H0 Key Project, which used WFPC2 to identify and photometer Cepheids in 31 spiral galaxies at distances from 60 to 400 Mpc. On the other, HST is the prime instrument for investigating cosmic acceleration by searching for and following Type Ia supernovae at moderate and high redshift. These two cosmological parameters are directly related, and recent years have seen renewed interest in improving the accuracy of H0 with the realization that such measurements, when coupled with the improved constraints from the Cosmic Microwave Background, provide important constraints on cosmic acceleration and the nature of Dark Energy. Previous HST programs have focused on identifying and measuring light curves for cepheids in external galaxies (eg GO 10802 , GO 11570 ) or quantifying the effects of variations in intrinsic stellar parameters, such as metallicity (eg GO 10918 , GO 11297 ). The present SNAP program is part of a suite of HST programs focusing on the Galactic Cepheids that form the foundation for the whole distance ladder. These programs employ a revived version of an old technique to determine both accurate astrometry, hence trigonometric parallaxes and reliable distances, and accurate photometry, hence flux emasurements. The technique is drift-scanning - tracking HST during the observation so that stars form trails on the detector. This mode of observations was available in the early years of HST's operations, and has been revived primarily as a means of obtaining high signal-to-noise grism spectroscolpic data of stars hosting transiting exoplanets. However, the same technique can be used in imaging mode, and the extended trails allow not only multiple measurements of position differences for stars in the field but also extremely high signal-to-noise photometry. The latter is crucial in obtaining direct photometry of tghe local calibrations on the same HST system, the same system that is being used for photometry of Cepheids in the external galaxies that serve as the basis for the distance scale. The present SNAP program includes 67 longer-period Galactic Cepheids. |
GO 13517: WISP - A Survey of Star Formation Across Cosmic Time
A region of massive star formation |
Star formation is the key astrophysical process in determining the overall evolution of galactic systems, the generation of heavy elements, and the overall enrichment of interstellar and intergalactic material. Tracing the overall evolution through a wide redshift range is crucial to understanding how gas and stars evolved to form the galaxies that we see around us now. The present program builds on the ability of HST to carry out parallel observations, using more than one instrument. While the Cosmic Origins Spectrograph is focused on obtaining ultraviolet spectra of unparalleled signal-to-noise, this program uses the near-infrared grisms mounted on the Wide-Field Camera 3 infrared channel to obtain low resolution spectra between 1 and 1.6 microns of randomly-selected nearby fields. The goal is to search for emission lines characteristic of star-forming regions. In particular, these observations are capable of detecting Lyman-alpha emission generated by star formation at redshifts z > 5.6. A total of up to 40 "deep" (4-5 orbit) and 20 "shallow" (2-3 orbit) fields will be targeted in the course of this observing campaign. |
GO 13829: The ice plumes of Europa
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. HST is currentply undertaking two programs that build on those observations - GO 13679 and GO 13829. The present program is using UV imaging and spectroscopy with the ACS Solar Blind Camera is searching for fluorescence, with the majority ofthe observations will be taken while Europa is in eclipse. Those observations will be matched against reference data taken out of eclipse. |
GO 13871: A Spectroscopic Redshift for the Most Luminous Galaxy Candidate at z~10
ACS images of a section of the GOODS fields |
The Great Observatories Origins Deep Survey, GOODS, originated as a Spitzer Legacy program coupled with a Cycle 12 HST Treasury program. The program was designed to probe galaxy formation and evolution at redshifts from z~1 to z~6. GOODS covers two ~150 sq. arcminute fields, one centred on the Hubble Deep Field in Ursa Major and the Chandra Deep Field-South in Fornax. Initially, the program combined deep optical/far-red imaging (F435W, F606W, F775W and F850LP filters) using ACS on HST with deep IRAC (3.6 to 8 micron) and MIPS (25 micron) imaging with Spitzer. These two fields have become among the most studied celestial regions. In addition to deep HST data at optical and near-infrared wavelengths (both fields have been covered by NICMOS), the fields have been covered at X-ray wavelengths by Chandra (obviously) and XMM-Newton, and ground-based imaging and spectroscopy using numerous telescopes, including the Kecks, Gemini, Surbaru and the ESO VLT. Part of the GOODS South field was covered by the WFC3 Early Release Science observations (see WFC3 ERS ), and both fields are also covered partially by one of the three Multi-Cycle Treasury programs allocated time in Cycle 18-20. Combining all these imaging data, Oesch et al have recently identified four surprisingly bright galaxies with photometric redshifts exceeding z=9. One of these objects, GN-z10-1, is placed at erdshift z=103., less than 500 Myrs after the Big Bang. The detection of such a luminous and (presumably) massive object at such a young epoch is surprising. The present program aims to solidify the observational result by using the WFC3-IR G141 grism to obtain a spectrum and determine a spectroscopic redshift for the object. |