Daily Rpt #4788

HUBBLE SPACE TELESCOPE - Continuing to collect World Class Science

DAILY REPORT****** #4788

PERIOD COVERED: 5am February 09 - 5am February 10, 2009 (DOY
******************* 040/1000z-041/1000z)

OBSERVATIONS SCHEDULED

ACS/SBC 11566

Imaging Saturn's Equinoctal Auroras

Auroral emissions provide an indispensable diagnostic tool for the
energetic processes occurring in planetary magnetospheres. In 2009
Saturn will reach equinox for the first time since the advent of
high-sensitivity planetary ultraviolet (UV) auroral imaging, offering
a unique, transient opportunity to observe both polar auroral regions
simultaneously. The observations proposed here will not only provide
the best images to date of Saturn's northern auroras, they will
address three fundamental issues: (1) Are Saturn's auroras similar in
the north and south? This will reveal the nature of the processes that
cause the northern auroras, and verify the multipole nature of
Saturn's internal magnetic field. (2) Is the location of the northern
auroral emission symmetric with to the south? This will indicate why
the southern auroral oval is displaced a few degrees toward midnight
from the spin pole. It will also reveal whether the oscillation
observed in the location of the southern auroral oval is similarly
observed in the north, illuminating the nature of near-planetary
period oscillations observed throughout the magnetosphere and
potentially providing a value for the elusive rotation period of the
deep interior. (3) What is the influence of equinox on the
magnetosphere? The unique orientation of the planetary spin axis at
equinox will reveal whether the auroras are influenced by the
direction of the interplanetary magnetic field, and whether the Sun's
effect on Saturn's magnetosphere changes throughout the planet's
seasons. The Hubble Space Telescope is the only instrument capable of
providing global instantaneous coverage of Saturn's UV auroras, and
since Saturn's orbital period is ~30 years, Cycle 17 is the only
opportunity to make these observations.

FGS 11788

The Architecture of Exoplanetary Systems

Are all planetary systems coplanar? Concordance cosmogony makes that
prediction. It is, however, a prediction of extrasolar planetary
system architecture as yet untested by direct observation for main
sequence stars other than the Sun. To provide such a test, we propose
to carry out FGS astrometric studies on four stars hosting seven
companions. Our understanding of the planet formation process will
grow as we match not only system architecture, but formed planet mass
and true distance from the primary with host star characteristics for
a wide variety of host stars and exoplanet masses.

We propose that a series of FGS astrometric observations with
demonstrated 1 millisecond of arc per-observation precision can
establish the degree of coplanarity and component true masses for four
extrasolar systems: HD 202206 (brown dwarf+planet); HD 128311
(planet+planet), HD 160691 = mu Arae (planet+planet), and HD 222404AB
= gamma Cephei (planet+star). In each case the companion is identified
as such by assuming that the minimum mass is the actual mass. For the
last target, a known stellar binary system, the companion orbit is
stable only if coplanar with the AB binary orbit.

WFPC2 11196

An Ultraviolet Survey of Luminous Infrared Galaxies in the Local
Universe

At luminosities above 10^11.4 L_sun, the space density of far-infrared
selected galaxies exceeds that of optically selected galaxies. These
Luminous Infrared Galaxies {LIRGs} are primarily interacting or
merging disk galaxies undergoing starbursts and creating/fueling
central AGN. We propose far {ACS/SBC/F140LP} and near {WFPC2/PC/F218W}
UV imaging of a sample of 27 galaxies drawn from the complete IRAS
Revised Bright Galaxy Sample {RBGS} LIRGs sample and known, from our
Cycle 14 B and I-band ACS imaging observations, to have significant
numbers of bright {23 B 21 mag} star clusters in the central 30
arcsec. The HST UV data will be combined with previously obtained HST,
Spitzer, and GALEX images to {i} calculate the ages of the clusters as
function of merger stage, {ii} measure the amount of UV light in
massive star clusters relative to diffuse regions of star formation,
{iii} assess the feasibility of using the UV slope to predict the
far-IR luminosity {and thus the star formation rate} both among and
within IR-luminous galaxies, and {iv} provide a much needed catalog of
rest- frame UV morphologies for comparison with rest-frame UV images
of high-z LIRGs and Lyman Break Galaxies. These observations will
achieve the resolution required to perform both detailed photometry of
compact structures and spatial correlations between UV and redder
wavelengths for a physical interpretation our IRX-Beta results. The
HST UV data, combined with the HST ACS, Spitzer, Chandra, and GALEX
observations of this sample, will result in the most comprehensive
study of luminous starburst galaxies to date.

WFPC2 11302

WFPC2 CYCLE 16 Standard Darks - Part III

This dark calibration program obtains dark frames every week in order
to provide data for the ongoing calibration of the CCD dark current
rate, and to monitor and characterize the evolution of hot pixels.
Over an extended period these data will also provide a monitor of
radiation damage to the CCDs.

WFPC2 11793

WFPC2 Cycle 16 Internal Monitor

This calibration proposal is the Cycle 15 routine internal monitor for
WFPC2, to be run weekly to monitor the health of the cameras. A
variety of internal exposures are obtained in order to provide a
monitor of the integrity of the CCD camera electronics in both bays
(both gain 7 and gain 15 -- to test stability of gains and bias
levels), a test for quantum efficiency in the CCDs, and a monitor for
possible buildup of contaminants on the CCD windows. These also
provide raw data for generating annual super-bias reference files for
the calibration pipeline.

WFPC2 11966

The Recent Star Formation History of SINGS Galaxies

The Spitzer Legacy project SINGS provided a unique view of the current
state of star formation and dust in a sample of galaxies of all Hubble
types. This multi-wavelength view allowed the team to create current
star formation diagnostics that are independent of the dust content
and increased our understanding of the dust in galaxies. Even so,
using the SINGS data alone we can only make rough estimates of the
recent star formation history of these galaxies. The lack of high
resolution observations (especially U-band and H-alpha) means that it
is impossible to estimate the ages of young clusters. In addition, the
low resolution of the Spitzer and ground-based observations means that
what appear to be individual Spitzer sources can actually be composed
of many individual clusters with varying ages. We need to know the
ages, star formation histories, and extinction of these individual
clusters to understand how these clusters form and age and thus
influence the evolution of the galaxy. In this proposal we address
this missing area of SINGS by obtaining high-resolution WFPC2 UBVI &
H-alpha observations to not only accurately locate and determine the
ages of the young stellar clusters in the actively star forming SINGS
galaxies but to also address a variety of other scientific issues.
Over 500 HST orbits and 500 hours of Spitzter observing time have been
dedicated to observations of the SINGS sample. But the HST
observations have not been systematic. By adding a relatively small
fraction of this time for these requested observations, we will
greatly enhance the legacy value of the SINGS observations by creating
a uniform high resolution multi-wavelength HST archive that matches
the quality of the lower resolution SINGS archive.

WFPC2 11967

WFPC2 Imaging of the Lockman Hole

In order to understand galaxy evolution and constrain theoretical
models, we require both multiwavelength photometry (to robustly
determine physical parameters such as star formation rates and stellar
masses) and detailed morphological information. Galaxy morphology
encodes crucial information about galaxy formation history and the
physical processes that trigger star formation and AGN activity, and
high-resolution imaging for large samples of galaxies is currently
only obtainable with HST. The Lockman Hole has been the target of
extensive multi-wavelength observations from the X-ray to the radio,
and will be the target of the deepest wide-area blankfield thermal IR
observations with Herschel, but currently lacks comprehensive HST
imaging. We propose to obtain WFPC2 imaging of ~500 arcmin2 of the
central region of the Lockman Hole in F606W and F814W, to a depth of
V606~26.8 and I814~26. This imaging is crucial in order to
characterize the sources detected at other wavelengths.

FLIGHT OPERATIONS SUMMARY:

Significant Spacecraft Anomalies: (The following are preliminary
reports of potential non-nominal performance that will be
investigated.)

HSTARS: (None)

COMPLETED OPS REQUEST: (None)

COMPLETED OPS NOTES: (None)

************************************ SCHEDULED***** SUCCESSFUL

FGS GSAcq************************* 07******************** 07
FGS REAcq************************* 07******************** 07
OBAD with Maneuver**************** 28******************** 28

SIGNIFICANT EVENTS: (None)