73 research outputs found
ExploreNEOs I: Description and first results from the Warm Spitzer NEO Survey
We have begun the ExploreNEOs project in which we observe some 700 Near Earth
Objects (NEOs) at 3.6 and 4.5 microns with the Spitzer Space Telescope in its
Warm Spitzer mode. From these measurements and catalog optical photometry we
derive albedos and diameters of the observed targets. The overall goal of our
ExploreNEOs program is to study the history of near-Earth space by deriving the
physical properties of a large number of NEOs. In this paper we describe both
the scientific and technical construction of our ExploreNEOs program. We
present our observational, photometric, and thermal modeling techniques. We
present results from the first 101 targets observed in this program. We find
that the distribution of albedos in this first sample is quite broad, probably
indicating a wide range of compositions within the NEO population. Many objects
smaller than one kilometer have high albedos (>0.35), but few objects larger
than one kilometer have high albedos. This result is consistent with the idea
that these larger objects are collisionally older, and therefore possess
surfaces that are more space weathered and therefore darker, or are not subject
to other surface rejuvenating events as frequently as smaller NEOs.Comment: AJ in pres
ExploreNEOs. II. The Accuracy of the Warm Spitzer Near-Earth Object Survey
We report on results of observations of near-Earth objects (NEOs) performed with the NASA Spitzer Space Telescope as part of our ongoing (2009-2011) Warm Spitzer NEO survey ("ExploreNEOs"), the primary aim of which is to provide sizes and albedos of some 700 NEOs. The emphasis of the work described here is an assessment of the overall accuracy of our survey results, which are based on a semi-empirical generalized model of asteroid thermal emission. The NASA Spitzer Space Telescope has been operated in the so-called Warm Spitzer mission phase since the cryogen was depleted in 2009 May, with the two shortest-wavelength channels, centered at 3.6 μm and 4.5 μm, of the Infrared Array Camera continuing to provide valuable data. The set of some 170 NEOs in our current Warm Spitzer results catalog contains 28 for which published taxonomic classifications are available, and 14 for which relatively reliable published diameters and albedos are available. A comparison of the Warm Spitzer results with previously published results ("ground truth"), complemented by a Monte Carlo error analysis, indicates that the rms Warm Spitzer diameter and albedo errors are ±20% and ±50%, respectively. Cases in which agreement with results from the literature is worse than expected are highlighted and discussed; these include the potential spacecraft target 138911 2001 AE_2. We confirm that 1.4 appears to be an appropriate overall default value for the relative reflectance between the V band and the Warm Spitzer wavelengths, for use in correction of the Warm Spitzer fluxes for reflected solar radiation
ExploreNEOs. III. Physical Characterization of 65 Potential Spacecraft Target Asteroids
Space missions to near-Earth objects (NEOs) are being planned at all major space agencies, and recently a manned mission to an NEO was announced as a NASA goal. Efforts to find and select suitable targets (plus backup targets) are severely hampered by our lack of knowledge of the physical properties of dynamically favorable NEOs. In particular, current mission scenarios tend to favor primitive low-albedo objects. For the vast majority of NEOs, the albedo is unknown. Here we report new constraints on the size and albedo of 65 NEOs with rendezvous Δv <7 km s^(–1). Our results are based on thermal-IR flux data obtained in the framework of our ongoing (2009-2011) ExploreNEOs survey using NASA's "Warm-Spitzer" space telescope. As of 2010 July 14, we have results for 293 objects in hand (including the 65 low-Δv NEOs presented here); before the end of 2011, we expect to have measured the size and albedo of ~700 NEOs (including probably ~160 low-Δv NEOs). While there are reasons to believe that primitive volatile-rich materials are universally low in albedo, the converse need not be true: the orbital evolution of some dark objects likely has caused them to lose their volatiles by coming too close to the Sun. For all our targets, we give the closest perihelion distance they are likely to have reached (using orbital integrations from Marchi et al. 2009) and corresponding upper limits on the past surface temperature. Low-Δv objects for which both albedo and thermal history may suggest a primitive composition include (162998) 2001 SK162, (68372) 2001 PM9, and (100085) 1992 UY4
Mid-infrared Photometric Analysis of Main Belt Asteroids: A Technique for Color-Color Differentiation from Background Astrophysical Sources
The Spitzer Space Telescope routinely detects asteroids in astrophysical observations near the ecliptic plane. For the galactic or extragalactic astronomer, these solar system bodies can introduce appreciable uncertainty into the source identification process. We discuss an infrared color discrimination tool that may be used to distinguish between solar system objects and extrasolar sources. We employ four Spitzer Legacy data sets, the First Look Survey-Ecliptic Plane Component (FLS-EPC), SCOSMOS, SWIRE, and GOODS. We use the Standard Thermal Model to derive FLS-EPC main belt asteroid (MBA) diameters of 1-4 km for the numbered asteroids in our sample and note that several of our solar system sources may have fainter absolute magnitude values than previously thought. A number of the MBAs are detected at flux densities as low as a few tens of μJy at 3.6 μm. As the FLS-EPC provides the only 3.6-24.0 μm observations of individual asteroids to date, we are able to use this data set to carry out a detailed study of asteroid color in comparison to astrophysical sources observed by SCOSMOS, SWIRE, and GOODS. Both SCOSMOS and SWIRE have identified a significant number of asteroids in their data, and we investigate the effectiveness of using relative color to distinguish between asteroids and background objects. We find a notable difference in color in the IRAC 3.6-8.0 mm and MIPS 24 μm bands between the majority of MBAs, stars, galaxies, and active galactic nuclei, though this variation is less significant when comparing fluxes in individual bands. We find median colors for the FLS-EPC asteroids to be [F(5.8/3.6), F(8.0/4.5), F(24/8)] = (4.9 ± 1.8, 8.9 ± 7.4, 6.4 ± 2.3). Finally, we consider the utility of this technique for other mid-infrared observations that are sensitive to near-Earth objects, MBAs, and trans-Neptunian objects. We consider the potential of using color to differentiate between solar system and background sources for several space-based observatories, including Warm Spitzer, Herschel, and WISE
Gas Accretion in Star-Forming Galaxies
Cold-mode gas accretion onto galaxies is a direct prediction of LCDM
simulations and provides galaxies with fuel that allows them to continue to
form stars over the lifetime of the Universe. Given its dramatic influence on a
galaxy's gas reservoir, gas accretion has to be largely responsible for how
galaxies form and evolve. Therefore, given the importance of gas accretion, it
is necessary to observe and quantify how these gas flows affect galaxy
evolution. However, observational data have yet to conclusively show that gas
accretion ubiquitously occurs at any epoch. Directly detecting gas accretion is
a challenging endeavor and we now have obtained a significant amount of
observational evidence to support it. This chapter reviews the current
observational evidence of gas accretion onto star-forming galaxies.Comment: Invited review to appear in Gas Accretion onto Galaxies, Astrophysics
and Space Science Library, eds. A. J. Fox & R. Dav\'e, to be published by
Springer. This chapter includes 22 pages with 7 Figure
Circumstellar Material in Type Ia Supernovae via Sodium Absorption Features
Type Ia supernovae are key tools for measuring distances on a cosmic scale.
They are generally thought to be the thermonuclear explosion of an accreting
white dwarf in a close binary system. The nature of the mass donor is still
uncertain. In the single-degenerate model it is a main-sequence star or an
evolved star, whereas in the double-degenerate model it is another white dwarf.
We show that the velocity structure of absorbing material along the line of
sight to 35 type Ia supernovae tends to be blueshifted. These structures are
likely signatures of gas outflows from the supernova progenitor systems. Thus
many type Ia supernovae in nearby spiral galaxies may originate in
single-degenerate systems.Comment: Accepted for publication in Science 5 July 201
Gas Accretion via Lyman Limit Systems
In cosmological simulations, a large fraction of the partial Lyman limit
systems (pLLSs; 16<log N(HI)<17.2) and LLSs (17.2log N(HI)<19) probes
large-scale flows in and out of galaxies through their circumgalactic medium
(CGM). The overall low metallicity of the cold gaseous streams feeding galaxies
seen in these simulations is the key to differentiating them from metal rich
gas that is either outflowing or being recycled. In recent years, several
groups have empirically determined an entirely new wealth of information on the
pLLSs and LLSs over a wide range of redshifts. A major focus of the recent
research has been to empirically determine the metallicity distribution of the
gas probed by pLLSs and LLSs in sizable and representative samples at both low
(z2) redshifts. Here I discuss unambiguous evidence for
metal-poor gas at all z probed by the pLLSs and LLSs. At z<1, all the pLLSs and
LLSs so far studied are located in the CGM of galaxies with projected distances
<100-200 kpc. Regardless of the exact origin of the low-metallicity pLLSs/LLSs,
there is a significant mass of cool, dense, low-metallicity gas in the CGM that
may be available as fuel for continuing star formation in galaxies over cosmic
time. As such, the metal-poor pLLSs and LLSs are currently among the best
observational evidence of cold, metal-poor gas accretion onto galaxies.Comment: Invited review to appear in Gas Accretion onto Galaxies, Astrophysics
and Space Science Library, eds. A. J. Fox & R. Dav\'e, to be published by
Springe
The Afterglows, Redshifts, and Properties of Swift Gamma-Ray Bursts
We present optical, near-IR, and radio follow up of sixteen Swift bursts,
including our discovery of nine afterglows and a redshift determination for
three. These observations, supplemented by data from the literature, provide an
afterglow recovery rate of 60% in the optical/near-IR, much higher than in
previous missions (BeppoSAX, HETE-2, INTEGRAL, and IPN). The optical/near-IR
afterglows of Swift events are on average 1.7 mag fainter at t=12 hr than those
of previous missions. The X-ray afterglows are similarly fainter compared to
those of pre-Swift bursts. In the radio the limiting factor is the VLA
threshold and the detection rate for Swift bursts is similar to that for past
missions. The redshift distribution of pre-Swift bursts peaked at z~1, whereas
the five Swift bursts with measured redshifts are distributed evenly between
1.3 and 3.2. From these results we conclude that (i) the pre-Swift
distributions were biased in favor of bright events and low redshift events,
(ii) the higher sensitivity and accurate positions of Swift result in a better
representation of the true burst redshift and brightness distributions (which
are higher and dimmer, respectively), and (iii) as many as 1/3 of the bursts
can be optically dark, as a result of a high redshift and/or dust extinction.
We remark that the apparent lack of low redshift, low luminosity Swift bursts,
and the lower event rate compared to pre-launch estimates (90 vs. 150 per
year), are the result of a threshold that is similar to that of BATSE. In view
of these inferences, afterglow observers may find it advisable to make
significant changes in follow up strategies of Swift events. [abridged]Comment: Submitted to ApJ; 15 pages, 8 figures, 1 tabl
The Fast, Luminous Ultraviolet Transient AT2018cow: Extreme Supernova, or Disruption of a Star by an Intermediate-Mass Black Hole?
Wide-field optical surveys have begun to uncover large samples of fast
(t_rise < 5d), luminous (M_peak < -18), blue transients. While commonly
attributed to the breakout of a supernova shock into a dense wind, the great
distances to the transients of this class found so far have hampered detailed
investigation of their properties. We present photometry and spectroscopy from
a comprehensive worldwide campaign to observe AT2018cow (ATLAS18qqn), the first
fast-luminous optical transient to be found in real time at low redshift. Our
first spectra (<2 days after discovery) are entirely featureless. A very broad
absorption feature suggestive of near-relativistic velocities develops between
3-8 days, then disappears. Broad emission features of H and He develop after
>10 days. The spectrum remains extremely hot throughout its evolution, and the
photospheric radius contracts with time (receding below R<10^14 cm after 1
month). This behaviour does not match that of any known supernova, although a
relativistic jet within a fallback supernova could explain some of the observed
features. Alternatively, the transient could originate from the disruption of a
star by an intermediate-mass black hole, although this would require
long-lasting emission of highly super-Eddington thermal radiation. In either
case, AT2018cow suggests that the population of fast luminous transients
represents a new class of astrophysical event. Intensive follow-up of this
event in its late phases, and of any future events found at comparable
distance, will be essential to better constrain their origins.Comment: Corrected Figure 8 / Table 4 to use final fits. Includes
machine-readable photometry table (hopefully for real this time
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