42 research outputs found
Single Event Effect Testing of the Micron MT46V128M8
The Micron MT46V128M8 was tested for single event effects (SEE) at the Texas AM University Cyclotron Facility (TAMU) in June of 2017. Testing revealed a sensitivity to device hang-ups classified as single event functional interrupts (SEFI) and possible soft data errors classified as single event upsets (SEU)
A Photometric System for Detection of Water and Methane Ices on Kuiper Belt Objects
We present a new near-infrared photometric system for detection of water ice
and methane ice in the solar system. The system consists of two medium-band
filters in the K-band region of the near-infrared, which are sensitive to water
ice and methane ice, plus continuum observations in the J-band and Y-band. The
primary purpose of this system is to distinguish between three basic types of
Kuiper Belt Objects (KBOs) --- those rich in water ice, those rich in methane
ice, and those with little absorbance. In this work, we present
proof-of-concept observations of 51 KBOs using our filter system, 21 of which
have never been observed in the near-IR spectroscopically. We show that our
custom photometric system is consistent with previous spectroscopic
observations while reducing telescope observing time by a factor of 3. We use
our filters to identify Haumea collisional family members, which are thought to
be collisional remnants of a much larger body and are characterized by large
fractions of water ice on their surfaces. We add 2009 YE7 to the Haumea
collisional family based on our water ice band observations(J-H2O = -1.03 +/-
0.27) which indicate a high amount of water ice absorption, our calculated
proper orbital elements, and the neutral optical colors we measured, V-R = 0.38
+/- 0.04, which are all consistent with the rest of the Haumea family. We
identify several objects dynamically similar to Haumea as being distinct from
the Haumea family as they do not have water ice on their surfaces. In addition,
we find that only the largest KBOs have methane ice, and we find that Haumea
itself has significantly less water ice absorption than the smaller Haumea
family members. We find no evidence for other families in the Kuiper Belt.Comment: 38 pages, 7 figure
Near-Infrared Spectral Monitoring of Triton with IRTF/SpeX II: Spatial Distribution and Evolution of Ices
This report arises from an ongoing program to monitor Neptune's largest moon
Triton spectroscopically in the 0.8 to 2.4 micron range using IRTF/SpeX. Our
objective is to search for changes on Triton's surface as witnessed by changes
in the infrared absorption bands of its surface ices N2, CH4, H2O, CO, and CO2.
We have recorded infrared spectra of Triton on 53 nights over the ten
apparitions from 2000 through 2009. The data generally confirm our previously
reported diurnal spectral variations of the ice absorption bands (Grundy &
Young 2004). Nitrogen ice shows a large amplitude variation, with much stronger
absorption on Triton's Neptune-facing hemisphere. We present evidence for
seasonal evolution of Triton's N2 ice: the 2.15 micron absorption band appears
to be diminishing, especially on the Neptune-facing hemisphere. Although it is
mostly dissolved in N2 ice, Triton's CH4 ice shows a very different
longitudinal variation from the N2 ice, challenging assumptions of how the two
ices behave. Unlike Triton's CH4 ice, the CO ice does exhibit longitudinal
variation very similar to the N2 ice, implying that CO and N2 condense and
sublimate together, maintaining a consistent mixing ratio. Absorptions by H2O
and CO2 ices show negligible variation as Triton rotates, implying very uniform
and/or high latitude spatial distributions for those two non-volatile ices.Comment: 22 pages, 13 figures, 5 tables, to appear in Icaru
A First Look at 22 nm FDSOI SRAM Single-Event Test Results
We will present the first ever single-event effects testing results on a 22 nm fully-depleted silicon-on-insulator test chip. The 128 MB SRAMs were irradiated with heavy ions and the results are compared to previous technology generations
Hunting planets and observing disks with the JWST NIRCam coronagraph
The expected stable point spread function, wide field of view, and sensitivity of the NIRCam instrument on the James Webb Space Telescope (JWST) will allow a simple, classical Lyot coronagraph to detect warm Jovian-mass companions orbiting young stars within 150 pc as well as cool Jupiters around the nearest low-mass stars. The coronagraph can also be used to study protostellar and debris disks. At λ = 4.5 μm, where young planets are particularly bright relative to their stars, and at separations beyond ~0.5 arcseconds, the low space background gives JWST significant advantages over ground-based telescopes equipped with adaptive optics. We discuss the scientific capabilities of the NIRCam coronagraph, describe the technical features of the instrument, and present end-to-end simulations of coronagraphic observations of planets and circumstellar disks
Coagulation Calculations of Icy Planet Formation at 15--150 AU: A Correlation Between the Maximum Radius and the Slope of the Size Distribution for Transneptunian Objects
We investigate whether coagulation models of planet formation can explain the
observed size distributions of transneptunian objects (TNOs). Analyzing
published and new calculations, we demonstrate robust relations between the
size of the largest object and the slope of the size distribution for sizes 0.1
km and larger. These relations yield clear, testable predictions for TNOs and
other icy objects throughout the solar system. Applying our results to existing
observations, we show that a broad range of initial disk masses, planetesimal
sizes, and fragmentation parameters can explain the data. Adding dynamical
constraints on the initial semimajor axis of `hot' KBOs along with probable TNO
formation times of 10-700 Myr restricts the viable models to those with a
massive disk composed of relatively small (1-10 km) planetesimals.Comment: Text: 44 pages, Tables: 5, Figures: 17; Accepted for publication in
the Astronomical Journa
Modeling the evolution of infrared galaxies: A Parametric backwards evolution model
We aim at modeling the infrared galaxy evolution in an as simple as possible
way and reproduce statistical properties among which the number counts between
15 microns and 1.1 mm, the luminosity functions, and the redshift
distributions. We then aim at using this model to interpret the recent
observations (Spitzer, Akari, BLAST, LABOCA, AzTEC, SPT and Herschel), and make
predictions for future experiments like CCAT or SPICA.
This model uses an evolution in density and luminosity of the luminosity
function with two breaks at redshift ~0.9 and 2 and contains the two
populations of the Lagache et al. (2004) model: normal and starburst galaxies.
We also take into account the effect of the strong lensing of high-redshift
sub-millimeter galaxies. It has 13 free parameters and 8 additional calibration
parameters. We fit the parameters to the IRAS, Spitzer, Herschel and AzTEC
measurements with a Monte-Carlo Markov chain.
The model ajusted on deep counts at key wavelengths reproduces the counts
from the mid-infrared to the millimeter wavelengths, as well as the
mid-infrared luminosity functions. We discuss the contribution to the cosmic
infrared background (CIB) and to the infrared luminosity density of the
different populations. We also estimate the effect of the lensing on the number
counts, and discuss the recent discovery by the South Pole Telescope (SPT) of a
very bright population lying at high-redshift. We predict confusion level for
future missions using a P(D) formalism, and the Universe opacity to TeV photons
due to the CIB.Comment: 25 pages, 10 tables, 18 figures, accepted for publication in A&
Searching for Planets Orbiting Fomalhaut with JWST/NIRCam
We report observations with the JWST/NIRCam coronagraph of the Fomalhaut
system. This nearby A star hosts a complex debris disk system discovered by the
IRAS satellite. Observations in F444W and F356W filters using the round 430R
mask achieve a contrast ratio of ~ 4 x 10-7 at 1'' and ~ 4 x 10-8 outside of
3''. These observations reach a sensitivity limit <1 MJup across most of the
disk region. Consistent with the hypothesis that Fomalhaut b is not a massive
planet but is a dust cloud from a planetesimal collision, we do not detect it
in either F356W or F444W (the latter band where a Jovian-sized planet should be
bright). We have reliably detected 10 sources in and around Fomalhaut and its
debris disk, all but one of which are coincident with Keck or HST sources seen
in earlier coronagraphic imaging; we show them to be background objects,
including the "Great Dust Cloud" identified in MIRI data. However, one of the
objects, located at the edge of the inner dust disk seen in the MIRI images,
has no obvious counterpart in imaging at earlier epochs and has a relatively
red [F356W]-[F444W]>0.7 mag (Vega) color. Whether this object is a background
galaxy, brown dwarf, or a Jovian mass planet in the Fomalhaut system will be
determined by an approved Cycle 2 follow-up program. Finally, we set upper
limits to any scattered light from the outer ring, placing a weak limit on the
dust albedo at F356W and F444W.Comment: 24 pages, 17 figure
Specific star-formation and the relation to stellar mass from 0<z<2 as seen in the far-infrared at 70 and 160mu
We use the Spitzer Wide-area InfraRed Extragalactic Legacy Survey (SWIRE) to
explore the specific star-formation activity of galaxies and their evolution
near the peak of the cosmic far-infrared (FIR) background at 70 and 160um. We
use a stacking analysis to determine the mean FIR properties of well defined
subsets of galaxies at flux levels well below the FIR catalogue detection
limits of SWIRE and other Spitzer surveys. We tabulate the contribution of
different subsets of galaxies to the FIR background at 70um and 160um. These
long wavelengths provide a good constraint on the bolometric, obscured
emission. The large area provides good constraints at low z and in finer
redshift bins than previous work. At all redshifts we find that the specific
FIR Luminosity (sLFIR) decreases with increasing mass, following a trend
L_FIR/M* propto M_* ^beta with beta =-0.38\pm0.14. This is a more continuous
change than expected from the {Delucia2007} semi-analytic model suggesting
modifications to the feedback prescriptions. We see an increase in the sLFIR by
about a factor of ~100 from 0<z<2 and find that the sLFIR evolves as
(1+z)^alpha with alpha=4.4\pm0.3 for galaxies with 10.5 < log M*/Msun < 12.
This is considerably steeper than the {Delucia2007} semi-analytic model (alpha
\sim 2.5). When separating galaxies into early and late types on the basis of
the optical/IR spectral energy distributions we find that the decrease in sLFIR
with stellar mass is stronger in early type galaxies (beta ~ -0.46), while late
type galaxies exhibit a flatter trend (beta \sim -0.15). The evolution is
strong for both classes but stronger for the early type galaxies. The early
types show a trend of decreasing strength of evolution as we move from lower to
higher masses while the evolution of the late type galaxies has little
dependence on stellar mass. We suggest that in late-type galaxies we are seeing
a consistently declining sSFR..Comment: v2 Update doesn't change the content of the paper, but now includes
data files for the plots Fig 5-13 (all.plotdat, spi.plotdat and ell.plotdat
on arXiv package
Hunting planets and observing disks with the JWST NIRCam coronagraph
The expected stable point spread function, wide field of view, and sensitivity of the NIRCam instrument on the James Webb Space Telescope (JWST) will allow a simple, classical Lyot coronagraph to detect warm Jovian-mass companions orbiting young stars within 150 pc as well as cool Jupiters around the nearest low-mass stars. The coronagraph can also be used to study protostellar and debris disks. At λ = 4.5 μm, where young planets are particularly bright relative to their stars, and at separations beyond ~0.5 arcseconds, the low space background gives JWST significant advantages over ground-based telescopes equipped with adaptive optics. We discuss the scientific capabilities of the NIRCam coronagraph, describe the technical features of the instrument, and present end-to-end simulations of coronagraphic observations of planets and circumstellar disks