Your search keyword '"Cruikshank, Dale P."' showing total 24 results

1. Volcanic Gases: Hydrogen Burning at Kilauea Volcano, Hawaii

Author

Cruikshank, Dale P., Morrison, David, and Lennon, Kenneth

Published

1973

2. Laboratory data on ices, refractory carbonaceous materials, and minerals relevant to transneptunian objects and Centaurs

Author

De Bergh, C., Schmitt, Bernard, Moroz, L. V., Quirico, Eric, Cruikshank, Dale P., Pibaret-Bourdon, Béatrice, Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Planétologie de Grenoble (LPG), Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), and NASA Ames Research Center (ARC)

Subjects

spectroscopy, Ceuntars, Transneptunian Objects, optical constants

Abstract

p. 483-506

Published

2008

3. Infrared spectroscopic characterization of the low-albedo materials on Iapetus

Author

Dalle Ore, Cristina Morea, Cruikshank, Dale P., and Clark, Roger N.

Subjects

*INFRARED spectroscopy, *ALBEDO, *DARK matter, *HYDROCARBONS, *RAYLEIGH scattering, *IAPETUS (Satellite), *SATELLITES of Saturn

Abstract

Abstract: Iapetus, one of the large satellites of Saturn, has been studied over the centuries for its signature brightness contrast, light on one side and dark on the opposite. It has recently been suggested that the dark material is a combination of native and exogenous materials with distinct histories. We present an analysis of parts of the Cassini Regio, the darkest region on the leading hemisphere of Iapetus, focusing on the hydrocarbon signature with a view to detect and investigate differences in the material(s). We find variations in the hydrocarbon bands with geographic location, one type predominantly located on the leading hemisphere. A comparison with the equivalent spectral features on Phoebe and Hyperion reveals a predictable resemblance between the leading hemisphere material and Phoebe and an unexpected likeness between Hyperion’s darkest material and Iapetus’ trailing hemisphere surface. An analysis of the slope in the visible part of the spectrum is strongly affected by a rise in the continuum (∼0.35–0.65μm) attributed to Rayleigh scattering from nano-size particles on the surface. The continuum rise varies in strength with the albedo and H2O ice content, and when it is properly accounted for, the overall slope in all the identified spectral units is the same over the interval 0.35–2.3μm, independent of albedo or ice abundance. The interpretation of current and previous results offers two different scenarios illustrated by the presence of one vs. two dark materials distributed over the Iapetus surface. We describe the scenarios and their implications. The appearance of the aromatic and aliphatic absorption bands together in their measured relative strengths makes this spectral signature unique, and thus enables the comparison among the three satellites. [Copyright &y& Elsevier]

Published

2012

4. The surface composition of Iapetus: Mapping results from Cassini VIMS

Author

Clark, Roger N., Cruikshank, Dale P., Jaumann, Ralf, Brown, Robert H., Stephan, Katrin, Dalle Ore, Cristina Morea, Eric Livo, K., Pearson, Neil, Curchin, John M., Hoefen, Todd M., Buratti, Bonnie J., Filacchione, Gianrico, Baines, Kevin H., and Nicholson, Philip D.

Subjects

*GEOCHEMISTRY, *CARTOGRAPHY, *HEMATITE, *RADIATIVE transfer, *AMMONIA, *IAPETUS (Satellite)

Abstract

Abstract: Cassini VIMS has obtained spatially resolved imaging spectroscopy data on numerous satellites of Saturn. A very close fly-by of Iapetus on September 10, 2007 provided the best data on the spectral signature and spatial extent of dark material on Iapetus. This Cassini Rev 49 Iapetus fly-by provided spatially resolved imaging spectroscopy data of the dark material and the leading/trailing side transition from the dark material to visually bright ice on the trailing side. Compositional mapping and radiative transfer modeling shows that the dark material is composed of metallic iron, nano-size iron oxide (hematite), CO2, H2O ice, and possible signatures of ammonia, bound water, H2 or OH-bearing minerals, trace organics, and as yet unidentified materials. CO2 indicates a pattern of increasing CO2 strength from the leading side apex to the transition zone to the icy trailing side. A Rayleigh scattering peak in the visible part of the spectrum indicates the dark material has a large component of fine, sub-0.5-μm diameter particles consistent with nanophase hematite and nanophase iron. Spectral signatures of ice also indicate that sub-0.5-μm diameter particles are present in the icy regions. Multiple lines of evidence point to an external origin for the dark material on Iapetus, including the global spatial pattern of dark material, local patterns including crater and cliff walls shielding implantation on slopes facing away from the leading side, exposing clean ice, and slopes facing the leading direction which show higher abundances of dark material. Multiple spectral features and overall spectral shape of the dark material on Iapetus match those seen on Phoebe, Hyperion, Dione, Epimetheus, Saturn’s rings Cassini Division, and the F-ring implying the material has a common composition throughout the Saturn system. The dark material appears to have significant components of nanophase metallic iron and nanophase hematite contributing to the observed UV absorption. The blue scattering peak with a strong UV–visible absorption is observed in spectra of all satellites that contain dark material, again pointing to a common origin of contamination by metallic iron that is partially oxidized. [Copyright &y& Elsevier]

Published

2012

5. Optical constants of Titan tholins at mid-infrared wavelengths (2.5–25μm) and the possible chemical nature of Titan’s haze particles

Author

Imanaka, Hiroshi, Cruikshank, Dale P., Khare, Bishun N., and McKay, Christopher P.

Subjects

*WAVELENGTHS, *OPTICAL constants, *HAZE, *REMOTE sensing, *LOW temperature plasmas, *GAS mixtures, *TITAN (Satellite)

Abstract

Abstract: Complex organic materials may exist as haze layers in the atmosphere of Titan and as dark coloring agents on icy satellite surfaces. Laboratory measurements of optical constants of plausible complex organic materials are necessary for quantitative evaluation from remote sensing observations, and to document the existence of complex organic materials in the extraterrestrial environments. The recent Cassini VIMS and CIRS observations provide new constraints on Titan’s haze properties in the mid-infrared wavelength region. Here, we present the optical constants (2.5–25μm) of Titan tholins generated with cold plasma irradiation of a N2/CH4 (90/10) gas mixture at pressures of 0.26mbar, 1.6mbar, and 23mbar. Our new optical constants of three types of Titan tholins suggest that no single Titan tholin in this study fulfills all the observational constraints of the Titan haze material. The discrepancy remains a challenge for future modeling and laboratory efforts that aim toward a better understanding of Titan’s haze material. [Copyright &y& Elsevier]

Published

2012

6. Hydrocarbons on Saturn's satellites Iapetus and Phoebe

Author

Cruikshank, Dale P., Wegryn, Eric, Dalle Ore, C.M., Brown, R.H., Bibring, J.-P., Buratti, B.J., Clark, R.N., McCord, T.B., Nicholson, P.D., Pendleton, Y.J., Owen, T.C., Filacchione, G., Coradini, A., Cerroni, P., Capaccioni, F., Jaumann, R., Nelson, R.M., Baines, K.H., Sotin, C., and Bellucci, G.

Subjects

*HYDROCARBONS, *SATELLITES of Saturn, *PHOEBE (Satellite), *SOLAR system

Abstract

Abstract: Material of low geometric albedo () is found on many objects in the outer Solar System, but its distribution in the saturnian satellite system is of special interest because of its juxtaposition with high-albedo ice. In the absence of clear, diagnostic spectral features, the composition of this low-albedo (or “dark”) material is generally inferred to be carbon-rich, but the form(s) of the carbon is unknown. Near-infrared spectra of the low-albedo hemisphere of Saturn''s satellite Iapetus were obtained with the Visible–Infrared Mapping Spectrometer (VIMS) on the Cassini spacecraft at the fly-by of that satellite of 31 December 2004, yielding a maximum spatial resolution on the satellite''s surface of ∼65 km. The spectral region 3–3.6 μm reveals a broad absorption band, centered at 3.29 μm, and concentrated in a region comprising about 15% of the low-albedo surface area. This is identified as the Cing mode vibration in polycyclic aromatic hydrocarbon (PAH) molecules. Two weaker bands attributed to -CH2- Stertching modes in aliphatic hydrocarbons are found in association with the aromatic band. The bands most likely arise from aromatic and aliphatic units in complex macromolecular carbonaceous material with a kerogen- or coal-like structure, similar to that in carbonaceous meteorites. VIMS spectra of Phoebe, encountered by Cassini on 11 June 2004, also show the aromatic hydrocarbon band, although somewhat weaker than on Iapetus. The origin of the PAH molecular material on these two satellites is unknown, but PAHs are found in carbonaceous meteorites, cometary dust particles, circumstellar dust, and interstellar dust. [Copyright &y& Elsevier]

Published

2008

7. Near-infrared spectra of laboratory H2O–CH4 ice mixtures

Author

Bernstein, Max P., Cruikshank, Dale P., and Sandford, Scott A.

Subjects

*INFRARED spectra, *CELESTIAL mechanics, *SPECTRUM analysis, *SOLAR system

Abstract

Abstract: We present 1.25–19 μm infrared spectra of pure solid CH4 and H2O/CH4=87, 20, and 3 solid mixtures at temperatures from 15 to 150 K. We compare and contrast the absorptions of CH4 in solid H2O with those of pure CH4. Changes in selected peak positions, profiles, and relative strength with temperature are presented, and absolute strengths for absorptions of CH4 in solid H2O are estimated. Using the two largest () and () near-IR absorptions of CH4 at 2.324 and 2.377 μm (4303 and 4207 cm−1), respectively, as examples, we show that peaks of CH4 in solid H2O are at slightly shorter wavelength (higher frequency) and broader than those of pure solid CH4. With increasing temperature, these peaks shift to higher frequency and become increasingly broad, but this trend is reversible on re-cooling, even though the phase transitions of H2O are irreversible. It is to be hoped that these observations of changes in the positions, profiles, and relative intensities of CH4 absorptions with concentration and temperature will be of use in understanding spectra of icy outer Solar System bodies. [Copyright &y& Elsevier]

Published

2006

8. Near-infrared laboratory spectra of solid H2O/CO2 and CH3OH/CO2 ice mixtures

Author

Bernstein, Max P., Cruikshank, Dale P., and Sandford, Scott A.

Subjects

*FROZEN desserts, *SPECTRUM analysis, *NATURAL satellites, *SOLAR system

Abstract

Abstract: We present near-IR spectra of solid CO2 in H2O and CH3OH, and find they are significantly different from that of pure solid CO2. Peaks not present in either pure H2O or pure CO2 spectra become evident when the two are mixed. First, the putative theoretically forbidden CO2 () overtone near 2.134 μm (4685 cm−1), that is absent from our spectrum of pure solid CO2, is prominent in the spectra of H2O/CO2=5 and 25 mixtures. Second, a 2.74-μm (3650 cm−1) dangling OH feature of H2O (and a potentially related peak at 1.89 μm) appear in the spectra of CO2–H2O ice mixtures, but are probably not diagnostic of the presence of CO2. Other CO2 peaks display shifts in position and increased width because of intermolecular interactions with H2O. Warming causes some peak positions and profiles in the spectrum of a H2O/CO2=5 mixture to take on the appearance of pure CO2. Absolute strengths for absorptions of CO2 in solid H2O are estimated. Similar results are observed for CO2 in solid CH3OH. Since the CO2 () overtone near 2.134 μm (4685 cm−1) is not present in pure CO2 but prominent in mixtures, it may be a good observational (spectral) indicator of whether solid CO2 is a pure material or intimately mixed with other molecules. These observations may be applicable to Mars polar caps as well as outer Solar System bodies. [Copyright &y& Elsevier]

Published

2005

9. A spectroscopic study of the surfaces of Saturn's large satellites: H2O ice, tholins, and minor constituents

Author

Cruikshank, Dale P., Owen, Tobias C., Ore, Cristina Dalle, Geballe, Thomas R., Roush, Ted L., de Bergh, Catherine, Sandford, Scott A., Poulet, Francois, Benedix, Gretchen K., and Emery, Joshua P.

Subjects

*SATELLITES of Saturn, *SPECTROSCOPIC imaging, *SPECTRUM analysis, *FROZEN desserts, *SPACE vehicles

Abstract

Abstract: We present spectra of Saturn''s icy satellites Mimas, Enceladus, Tethys, Dione, Rhea, and Hyperion, 1.0–2.5 μm, with data extending to shorter (Mimas and Enceladus) and longer (Rhea and Dione) wavelengths for certain objects. The spectral resolution () of the data shown here is in the range 800–1000, depending on the specific instrument and configuration used; this is higher than the resolution ( at 3 μm) afforded by the Visual-Infrared Mapping Spectrometer on the Cassini spacecraft. All of the spectra are dominated by water ice absorption bands and no other features are clearly identified. Spectra of all of these satellites show the characteristic signature of hexagonal H2O ice at 1.65 μm. We model the leading hemisphere of Rhea in the wavelength range 0.3–3.6 μm with the Hapke and the Shkuratov radiative transfer codes and discuss the relative merits of the two approaches to fitting the spectrum. In calculations with both codes, the only components used are H2O ice, which is the dominant constituent, and a small amount of tholin (Ice Tholin II). Tholin in small quantities (few percent, depending on the mixing mechanism) appears to be an essential component to give the basic red color of the satellite in the region 0.3–1.0 μm. The quantity and mode of mixing of tholin that can produce the intense coloration of Rhea and other icy satellites has bearing on its likely presence in many other icy bodies of the outer Solar System, both of high and low geometric albedos. Using the modeling codes, we also establish detection limits for the ices of CO2 (a few weight percent, depending on particle size and mixing), CH4 (same), and NH4OH (0.5 weight percent) in our globally averaged spectra of Rhea''s leading hemisphere. New laboratory spectral data for NH4OH are presented for the purpose of detection on icy bodies. These limits for CO2, CH4, and NH4OH on Rhea are also applicable to the other icy satellites for which spectra are presented here. The reflectance spectrum of Hyperion shows evidence for a broad, unidentified absorption band centered at 1.75 μm. [Copyright &y& Elsevier]

Published

2005

10. Quantitative modeling of the spectral reflectance of Kuiper Belt objects and Centaurs

Author

Cruikshank, Dale P., Roush, Ted L., and Poulet, François

Subjects

*KUIPER belt, *SPECTRAL reflectance, *SUNSHINE, *SOLAR system, *REFLECTANCE

Abstract

Reflectance spectroscopy of Solar System bodies provides a rich source of information on their compositions (minerals, ices, metals, and macromolecular carbon-bearing materials). Models calculated with radiative transfer theories for the spectral distribution of diffusely scattered sunlight from planetary surfaces yield information on the compositions, abundances, physical states, layering, and particle microstructure of those surfaces. We discuss and evaluate the scattering theories of Hapke and Shkuratov that are widely used for modeling the reflectance spectra and color data for Kuiper Belt objects, Centaur objects, and other airless bodies in the Solar System. Both theories yield good models of the reflectance spectrum of Centaur 5145 Pholus using five components (ices, carbon, a silicate mineral, and a complex organic material), although the derived abundances differ widely. To cite this article: D.P. Cruikshank et al., C. R. Physique 4 (2003). [Copyright &y& Elsevier]

Published

2003

11. Carbon dioxide on planetary bodies: Theoretical and experimental studies of molecular complexes

Author

Chaban, Galina M., Bernstein, Max, and Cruikshank, Dale P.

Subjects

*NATURAL satellites, *MOLECULES, *MATHEMATICAL transformations, *SPECTRUM analysis

Abstract

An absorption band at ～4.26μm wavelength attributed to the asymmetric stretching mode of Ce:inf CO2 has been found on two satellites of Jupiter and several satellites of Saturn. The wavelength of pure CO2 ice determined in the laboratory is 4.2675 μm, indicating that the CO2 on the satellites occurs either trapped in a host material, or in a chemical or physical complex with other materials, resulting in a blue shift of the wavelength of the band. In frequency units, the shifts in the satellite spectra range from 3.7 to 11.3 cm−1. We have performed ab initio quantum chemical calculations of CO2 molecules chemically complexed with one, two, and more H2O molecules and molecules of CH3OH to explore the possibility that the blue shift of the band is caused by chemical complexing of CO2 with other volatile materials. Our computations of the harmonic and anharmonic vibrational frequencies using high levels of theory show a frequency shift to the blue by 5 cm−1 from pure CO2 to CO–H2O, and an additional 5 cm−1 from CO2–H2O to CO2–2H2O. Complexing with more than two H2O molecules does not increase the blue shift. Complexes of CO2 with one molecule of CH3OH and with one CH3OH plus one H2O molecule produce smaller shifts than the CO2–2H2O complex. Laboratory studies of CO2:H2O in a solid N2 matrix also show a blue shift of the asymmetric stretching mode. [Copyright &y& Elsevier]

Published

2007

12. The distribution of H2O, CH3OH, and hydrocarbon-ices on Pluto: Analysis of New Horizons spectral images.

Author

Cook, Jason C., Dalle Ore, Cristina M., Protopapa, Silvia, Binzel, Richard P., Cruikshank, Dale P., Earle, Alissa, Grundy, William M., Ennico, Kimberly, Howett, Carly, Jennings, Donald E., Lunsford, Allen W., Olkin, Catherine B., Parker, Alex H., Philippe, Sylvain, Reuter, Dennis, Schmitt, Bernard, Singer, Kelsi, Stansberry, John A., Stern, S. Alan, and Verbiscer, Anne

Subjects

*SPECTRAL imaging, *PLUTO (Dwarf planet), *OPTICAL constants, *WATER, *SPACE sciences, *ICE

Abstract

• First detailed analysis of Pluto's H 2 O-ice rich sites. • Evidence for heavy hydrocarbons (i.e., C 3 H 8). • Test for CH 3 OH using new optical constants. On July 14, 2015, the New Horizons spacecraft made its closest approach to Pluto at about 12,000 km from its surface (Stern et al., 2015). Using the LEISA (Linear Etalon Imaging Spectral Array) near-IR imaging spectrometer we obtained two scans across the encounter hemisphere of Pluto at 6–7 km/pixel resolution. By correlating each spectrum with a crystalline H 2 O-ice model, we find several sites on Pluto's surface that exhibit the 1.5, 1.65 and 2.0 µm absorption bands characteristic of H 2 O-ice in the crystalline phase. These sites tend to be isolated and small (≲ 5000 km2 per site). We note a distinct near-IR blue slope over the LEISA wavelength range and asymmetries in the shape of the 2.0 µm H 2 O-ice band in spectra with weak CH 4 -ice bands and strong H 2 O-ice bands. These characteristics are indicative of fine-grain (grain diameters < wavelength or ∼ 1 µm) H 2 O-ice, like that seen in the spectra of Saturnian rings and satellites. However, the best-fit Hapke models require small mass fractions (≲10−3) of fine-grained H 2 O-ice that we can exchange for other refractory materials in the models with little change in χ 2, which may mean that the observed blue slope is possibly not due to a fine-grained material but an unidentified material with a similar spectral characteristic. We use these spectra to test for the presence of amorphous H 2 O-ice and estimate crystalline-to-amorphous H 2 O-ice fractions between 30 and 100%, depending on the location. We also see evidence for heavy hydrocarbons via strong absorption at λ > 2.3 µ m. Such heavy hydrocarbons are much less volatile than N 2 , CH 4 , and CO at Pluto temperatures. We test for CH 3 OH, C 2 H 6 , C 2 H 4 , and C 3 H 8 -ices because they have known optical constants and these ices are likely to arise from UV and energetic particle bombardment of the N 2 , CH 4 , CO-rich surface and atmosphere. Finally, we attempt to estimate the surface temperature using optical constants of pure CH 4 , and H 2 O-ice and best-fit Hapke models. Our standard model gives temperature estimates between 40 and 90 K, while our models including amorphous H 2 O-ice give lower temperature estimates between 30 and 65 K. [ABSTRACT FROM AUTHOR]

Published

2019

13. Composition of Pluto’s small satellites: Analysis of New Horizons spectral images.

Author

Cook, Jason C., Ore, Cristina M. Dalle, Protopapa, Silvia, Binzel, Richard P., Cartwright, Richard, Cruikshank, Dale P., Earle, Alissa, Grundy, William M., Ennico, Kimberly, Howett, Carly, Jennings, Donald E., Lunsford, Allen W., Olkin, Catherine B., Parker, Alex H., Philippe, Sylvain, Reuter, Dennis, Schmitt, Bernard, Stansberry, John A., Alan Stern, S., and Verbiscer, Anne

Subjects

*SPECTRAL imaging, *CRYSTALLINITY, *HELIOCENTRIC model (Astronomy), *STANDARD deviations, *CONTOURS (Cartography)

Abstract

Highlights • First spectral analysis of Nix, Hydra and Kerberos. • Crystalline water ice found on all three. • 2.21 µm band seen on Nix and Hydra indicating an ammoniated species. • Disk resolved spectroscopy of Nix. • Temperature and crystalline H2O-ice fraction estimated for Nix and Hydra. Abstract On July 14, 2015, NASA’s New Horizons spacecraft encountered the Pluto-system. Using the near-infrared spectral imager, New Horizons obtained the first spectra of Nix, Hydra, and Kerberos and detected the 1.5 and 2.0 µm bands of H 2 O-ice on all three satellites. On Nix and Hydra, New Horizons also detected bands at 1.65 and 2.21 µm that indicate crystalline H 2 O-ice and an ammoniated species, respectively. A similar band linked to NH 3 -hydrate has been detected on Charon previously. However, we do not detect the 1.99 µm band of NH 3 -hydrate. We consider NH 4 Cl (ammonium chloride), NH 4 NO 3 (ammonium nitrate) and (NH 4) 2 CO 3 (ammonium carbonate) as potential candidates, but lack sufficient laboratory measurements of these and other ammoniated species to make a definitive conclusion. We use the observations of Nix and Hydra to estimate the surface temperature and crystalline H 2 O-ice fraction. We find surface temperatures < 20 K (<70 K with 1- σ error) and 23 K (< 150 K with 1- σ error) for Nix and Hydra, respectively. We find crystalline H 2 O-ice fractions of 78 − 22 + 12 % and > 30% for Nix an Hydra, respectively. New Horizons observed Nix and Hydra twice, about 2–3 hours apart, or 5 and 25% of their respective rotation periods. We find no evidence for rotational differences in the disk-averaged spectra between the two observations of Nix or Hydra. We perform a pixel-by-pixel analysis of Nix’s disk-resolved spectra and find that the surface is consistent with a uniform crystalline H 2 O-ice fraction, and a ∼ 50% variation in the normalized band area of the 2.21 µm band with a minimum associated with the red blotch seen in color images of Nix. Finally, we find evidence for bands on Nix and Hydra at 2.42 and possibly 2.45 µm, which we cannot identify, and, if real, do not appear to be associated with the ammoniated species. We do not detect other ices, such as CO 2 , CH 3 OH and HCN. [ABSTRACT FROM AUTHOR]

Published

2018

14. Asteroid (16) Psyche: Evidence for a silicate regolith from spitzer space telescope spectroscopy.

Author

Landsman, Zoe A., Emery, Joshua P., Campins, Humberto, Hanuš, Josef, Lim, Lucy F., and Cruikshank, Dale P.

Subjects

*ASTEROIDS, *SILICATES, *PROTOPLANETARY disks, *ORIGIN of planets

Abstract

Asteroid (16) Psyche is a unique, metal-rich object belonging to the “M” taxonomic class. It may be a remnant protoplanet that has been stripped of most silicates by a hit-and-run collision. Because Psyche offers insight into the planetary formation process, it is the target of NASA’s Psyche mission, set to launch in 2023. In order to constrain Psyche’s surface properties, we have carried out a mid-infrared (5–14 µm) spectroscopic study using data collected with the Spitzer Space Telescope’s Infrared Spectrograph. Our study includes two observations covering different rotational phases. Using thermophysical modeling, we find that Psyche’s surface is smooth and likely has a thermal inertia Γ = 5–25 J/m 2 /K/s 1/2 and bolometric emissivity ϵ = 0.9, although a scenario with ϵ = 0.7 and thermal inertia up to 95 J/m 2 /K/s 1/2 is possible if Psyche is somewhat larger than previously determined. The smooth surface is consistent with the presence of a metallic bedrock, which would be more ductile than silicate bedrock, and thus may not readily form boulders upon impact events. From comparisons with laboratory spectra of silicate and meteorite powders, Psyche’s 7–14 µm emissivity spectrum is consistent with the presence of fine-grained (< 75 µm) silicates on Psyche’s surface. We conclude that Psyche is likely covered in a fine silicate regolith, which may also contain iron grains, overlying an iron-rich bedrock. [ABSTRACT FROM AUTHOR]

Published

2018

15. Analysis of Charon's spectrum at 2.21-[formula omitted] from New Horizons/LEISA and Earth-based observations.

Author

Cook, Jason C., Protopapa, Silvia, Dalle Ore, Cristina M., Cruikshank, Dale P., Grundy, William M., Lisse, Carey M., Schmitt, Bernard, Verbiscer, Anne, Singer, Kelsi N., Spencer, John, Stern, S. Alan, and Weaver, Harold A.

Subjects

*LONGITUDE, *SPECTRUM analysis, *PLUTO (Dwarf planet), *ROTATION of the earth, *FRACTIONS, *ABSORPTION

Abstract

We examine the 2.21- μ m band from 19 disk-integrated Charon spectra measured by New Horizons /LEISA in the week leading up to its closest encounter with the Pluto system. These observations cover one Charon rotation period. Additionally, we analyze Charon's 2.21- μ m band from 22 Earth-based spectra obtained over the last two decades. We measure the equivalent width of the 2.21- μ m band from all observations and study it as a function of sub-observer longitude. We find no significant variation in the 2.21- μ m band as Charon rotates. Compared to the same band seen on Nix and Hydra, Charon's 2.21- μ m band is several times weaker. We attribute the 2.21- μ m band to NH 4 Cl based on the appearance of a weaker band at 2.24- μ m. Furthermore, we see two never-before-reported absorption features in Charon's spectrum at 1.60 and 1.63- μ m , which may also be due to NH 4 Cl. If NH 3 -H 2 O-ice mixtures are present on Charon, they must be a small fraction of the disk-average composition to be consistent with the spectrum at 1.99- μ m. • First analysis of Charon spectra obtained by New Horizons on approach to the Pluto-system. • In-depth examination of the 2.21 μ m band using New Horizons and ground-based observations. • No variation in depth observed with respect to longitude, and much weaker absorption than Nix and Hydra. • Band at 2.24 μ m suggests NH 4 Cl is present and possible new spectral features are found at 1.60 and 1.63 μ m. • Formation, evolution, and destruction of NH 4 Cl discussed. [ABSTRACT FROM AUTHOR]

Published

2023

16. Saturn’s icy satellites investigated by Cassini-VIMS. IV. Daytime temperature maps.

Author

Filacchione, Gianrico, D’Aversa, Emiliano, Capaccioni, Fabrizio, Clark, Roger N., Cruikshank, Dale P., Ciarniello, Mauro, Cerroni, Priscilla, Bellucci, Giancarlo, Brown, Robert H., Buratti, Bonnie J., Nicholson, Phillip D., Jaumann, Ralf, McCord, Thomas B., Sotin, Christophe, Stephan, Katrin, and Dalle Ore, Cristina M.

Subjects

*SATELLITES of Saturn, *INFRARED spectroscopy, *REGOLITH, *WAVELENGTHS, *ASTRONOMICAL research

Abstract

The spectral position of the 3.6 µm continuum peak measured on Cassini-VIMS I/F spectra is used as a marker to infer the temperature of the regolith particles covering the surfaces of Saturn’s icy satellites. This feature is characterizing the crystalline water ice spectrum which is the dominant compositional endmember of the satellites’ surfaces. Laboratory measurements indicate that the position of the 3.6 μ m peak of pure water ice is temperature-dependent, shifting towards shorter wavelengths when the sample is cooled, from about 3.65 μ m at T =123 K to about 3.55 μ m at T =88 K. A similar method was already applied to VIMS Saturn’s rings mosaics to retrieve ring particles temperature (Filacchione, G., Ciarniello, M., Capaccioni, F., et al., 2014. Icarus , 241, 45-65). We report here about the daytime temperature variations observed on the icy satellites as derived from three different VIMS observation types: (a) a sample of 240 disk-integrated I/F observations of Saturn’s regular satellites collected by VIMS during years 2004–2011 with solar phase in the 20°–40° range, corresponding to late morning-early afternoon local times. This dataset is suitable to exploit the temperature variations at hemispherical scale, resulting in average temperature T <88 K for Mimas, T ≪88 K for Enceladus, T <88 K for Tethys, T =98–118 K for Dione, T =108–128 K for Rhea, T =118–128 K for Hyperion, T =128–148 and T > 168 K for Iapetus’ trailing and leading hemispheres, respectively. A typical ±5 K uncertainty is associated to the temperature retrieval. On Tethys and Dione, for which observations on both leading and trailing hemispheres are available, in average daytime temperatures higher of about 10 K on the trailing than on the leading hemisphere are inferred. (b) Satellites disk-resolved observations taken at 20–40 km pixel − 1 resolution are suitable to map daytime temperature variations across surfaces’ features, such as Enceladus’ tiger stripes and Tethys’ equatorial dark lens. These datasets allow to disentangle solar illumination conditions from temperature distribution when observing surface’s features with strong thermal contrast. (c) Daytime average maps covering large regions of the surfaces are used to compare the inferred temperature with geomorphological features (impact craters, chasmatae, equatorial radiation lenses and active areas) and albedo variations. Temperature maps are built by mining the complete VIMS dataset collected in years 2004–2009 (pre-equinox) and in 2009–2012 (post equinox) by selecting pixels with max 150 km pixel − 1 resolution. VIMS-derived temperature maps allow to identify thermal anomalies across the equatorial lens of Mimas and Tethys. A temperature T > 115K is measured above Enceladus’ Damascus and Alexandria sulci in the south pole region. VIMS has the sensitivity to follow seasonal temperature changes: on Tethys, Dione and Rhea higher temperature are measured above the south hemisphere during pre-equinox and above the north hemisphere during post-equinox epochs. The measured temperature distribution appears correlated with surface albedo features: in fact temperature increases on low albedo units located on Tethys, Dione and Rhea trailing hemispheres. The thermal anomaly region on Rhea’s Inktomi crater detected by CIRS (Howett, C. J. A., Spencer, J. R., Hurford, T., et al., 2014. Icarus , 241, 239–247) is confirmed by VIMS: this area appears colder with respect to surrounding terrains when observed at the same local solar time. [ABSTRACT FROM AUTHOR]

Published

2016

17. The Veritas and Themis asteroid families: 5–14 µm spectra with the Spitzer Space Telescope.

Author

Landsman, Zoe A., Licandro, Javier, Campins, Humberto, Ziffer, Julie, Prá, Mario de, and Cruikshank, Dale P.

Subjects

*ASTEROIDS, *SPECTRUM analysis, *NEAR infrared spectroscopy, *NEBULAR hypothesis, *EMISSIONS (Air pollution)

Abstract

Spectroscopic investigations of primitive asteroid families constrain family evolution and composition and conditions in the solar nebula, and reveal information about past and present distributions of volatiles in the solar system. Visible and near-infrared studies of primitive asteroid families have shown spectral diversity between and within families. Here, we aim to better understand the composition and physical properties of two primitive families with vastly different ages: ancient Themis (∼2.5 Gyr) and young Veritas (∼8 Myr). We analyzed the 5 – 14 µ m Spitzer Space Telescope spectra of 11 Themis-family asteroids, including eight previously studied by Licandro et al. (2012), and nine Veritas-family asteroids, for a total of 20 asteroids in our sample. We detect a broad 10- µ m emission feature, attributed to fine-grained and/or porous silicate regolith, in all 11 Themis-family spectra and six of nine Veritas-family asteroids, with 10- µ m spectral contrast ranging from 1% ± 0.1% to 8.5% ± 0.9%. We used thermal modeling to derive diameters, beaming parameters and albedos for our sample. Asteroids in both families have beaming parameters near unity and geometric albedos in the range 0.03 – 0.14. Spectral contrast of the 10- µ m silicate emission feature is correlated with beaming parameter and rotation period in the Themis family, and may be related to near-infrared spectral slope for both families. We see no correlations of 10- µ m emission with diameter or albedo for either family. Comparison with laboratory spectra of primitive meteorites suggests these asteroids are similar to meteorites with relatively low abundances of phyllosilicates. Overall, our results suggest the Themis and Veritas families are primitive asteroids with variation in composition and/or regolith properties within both families. [ABSTRACT FROM AUTHOR]

Published

2016

18. The Saturnian satellite Rhea as seen by Cassini VIMS

Author

Stephan, Katrin, Jaumann, Ralf, Wagner, Roland, Clark, Roger N., Cruikshank, Dale P., Giese, Bernd, Hibbitts, Charles A., Roatsch, Thomas, Matz, Klaus-Dieter, Brown, Robert H., Filacchione, Gianrico, Cappacioni, Fabrizio, Scholten, F., Buratti, Bonnie J., Hansen, Gary B., Nicholson, Phil D., Baines, Kevin H., Nelson, Robert M., and Matson, Dennis L.

Subjects

*SPECTROMETERS, *DIGITAL elevation models, *RHEA (Satellite), *DIONE (Satellite), *SATELLITES of Saturn, *SATURN (Planet)

Abstract

Abstract: Since the arrival of the Cassini spacecraft at Saturn in June 2004, the Visual and Infrared Mapping Spectrometer has obtained new spectral data of the icy satellites of Saturn in the spectral range from 0.35 to 5.2μm. Numerous flybys were performed at Saturn’s second largest satellite Rhea, providing a nearly complete coverage with pixel-ground resolutions sufficient to analyze variations of spectral properties across Rhea’s surface in detail. We present an overview of the VIMS observations obtained so far, as well as the analysis of the spectral properties identified in the VIMS spectra and their variations across its surface compared with spatially highly resolved Cassini ISS images and digital elevation models. Spectral variations measured across Rhea’s surface are similar to the variations observed in the VIMS observations of its neighbor Dione, implying similar processes causing or at least inducing their occurrence. Thus, magnetospheric particles and dust impacting onto the trailing hemisphere appear to be responsible for the concentration of dark rocky/organic material and minor amounts of CO2 in the cratered terrain on the trailing hemisphere. Despite the prominent spectral signatures of Rhea’s fresh impact crater Inktomi, radiation effects were identified that also affect the H2O ice-rich cratered terrain of the leading hemisphere. The concentration of H2O ice in the vicinity of steep tectonic scarps near 270°W and geologically fresh impact craters implies that Rhea exhibits an icy crust at least in the upper few kilometers. Despite the evidence for past tectonic events, no indications of recent endogenically powered processes could be identified in the Cassini data. [Copyright &y& Elsevier]

Published

2012

19. Iapetus surface variability revealed from statistical clustering of a VIMS mosaic: The distribution of CO2

Author

Pinilla-Alonso, Noemi, Roush, Ted L., Marzo, Giuseppe A., Cruikshank, Dale P., and Dalle Ore, Cristina M.

Subjects

*SPECTROSCOPIC imaging, *ABSORPTION spectra, *ENERGY bands, *CARBON dioxide, *GEOPHYSICS, *IAPETUS (Satellite), *PHOEBE (Satellite)

Abstract

Abstract: We present a detailed study of an Iapetus mosaic of VIMS data with high spatial resolution (0.5×0.5° or ∼6.4km/pixel). The spectra were taken in August 2007 and provide the highest VIMS spatial resolution data for this object during Cassini’s primary mission. We analyze this set of data using a statistical clustering approach to reduce the analysis of a large number of data (∼104 spectra from 0.35 to 5.10μm) to the study of seven representative groups accounting for 99.6% of the surface covered by the original sample. We analyze the spectral absorption bands in the spectra of the different clusters indicative of different composition over the observed surface. We find coherence between the distribution of the clusters and the geographical features on the surface. We give special attention to the study of the water ice and CO2 bands. We find that CO2 is widespread over the entire surface being studied, including the bright and dark areas on Iapetus’ surface, and is probably trapped at the molecular level with other materials. The strength of the CO2 band in the areas where both, H2O- and carbon-bearing materials exist, gives support to the hypothesis that this volatile is formed on the surface of Iapetus as a product of irradiation of these two components. Finally, we also compare the Iapetus CO2 with that on other satellites confirming, that there are evident differences on the center, depth and width of the band on Iapetus and Phoebe, where CO2 has been suggested to be endogenous. [Copyright &y& Elsevier]

Published

2011

20. A search for ethane on Pluto and Triton

Author

DeMeo, Francesca E., Dumas, Christophe, de Bergh, Catherine, Protopapa, Silvia, Cruikshank, Dale P., Geballe, Thomas R., Alvarez-Candal, Alvaro, Merlin, Frédéric, and Barucci, Maria A.

Subjects

*ASTRONOMICAL observations, *ETHANES, *NEAR infrared spectroscopy, *PLANETARY surfaces, *PLANETARY spectra, *PLUTO (Dwarf planet), *TRITON (Satellite)

Abstract

Abstract: We present here a search for solid ethane, C2H6, on the surfaces of Pluto and Triton, based on near-infrared spectral observations in the H and K bands (1.4–2.45μm) using the Very Large Telescope (VLT) and the United Kingdom Infrared Telescope (UKIRT). We model each surface using a radiative transfer model based on Hapke theory (Hapke, B. [1993]. Theory of Reflectance and Emittance Spectroscopy. Cambridge University Press, Cambridge, UK) with three basic models: without ethane, with pure ethane, and with ethane diluted in nitrogen. On Pluto we detect weak features near 2.27, 2.405, 2.457, and 2.461μm that match the strongest features of pure ethane. An additional feature seen at 2.317μm is shifted to longer wavelengths than ethane by at least 0.002μm. The strength of the features seen in the models suggests that pure ethane is limited to no more than a few percent of the surface of Pluto. On Triton, features in the H band could potentially be explained by ethane diluted in , however, the lack of corresponding features in the K band makes this unlikely (also noted by Quirico et al. (Quirico, E., Doute, S., Schmitt, B., de Bergh, C., Cruikshank, D.P., Owen, T.C., Geballe, T.R., Roush, T.L. [1999]. Icarus 139, 159–178)). While Cruikshank et al. (Cruikshank, D.P., Mason, R.E., Dalle Ore, C.M., Bernstein, M.P., Quirico, E., Mastrapa, R.M., Emery, J.P., Owen, T.C. [2006]. Bull. Am. Astron. Soc. 38, 518) find that the 2.406-μm feature on Triton could not be completely due to 13CO, our models show that it could not be accounted for entirely by ethane either. The multiple origin of this feature complicates constraints on the contribution of ethane for both bodies. [Copyright &y& Elsevier]

Published

2010

21. Dione’s spectral and geological properties

Author

Stephan, Katrin, Jaumann, Ralf, Wagner, Roland, Clark, Roger N., Cruikshank, Dale P., Hibbitts, Charles A., Roatsch, Thomas, Hoffmann, Harald, Brown, Robert H., Filiacchione, G., Buratti, Bonnie J., Hansen, Gary B., McCord, Tom B., Nicholson, Phil D., and Baines, Kevin H.

Subjects

*CARBON dioxide adsorption, *PLANETARY spectra, *PLANETARY geology, *IMAGING systems in astronomy, *MAGNETOSPHERIC physics, *DIONE (Satellite), *SATURN (Planet)

Abstract

Abstract: We present a detailed analysis of the variations in spectral properties across the surface of Saturn’s satellite Dione using Cassini/VIMS data and their relationships to geological and/or morphological characteristics as seen in the Cassini/ISS images. This analysis focuses on a local region on Dione’s anti-saturnian hemisphere that was observed by VIMS with high spatial resolution during orbit 16 in October 2005. The results are incorporated into a global context provided by VIMS data acquired within Cassini’s first 50 orbits. Our results show that Dione’s surface is dominated by at least one global process. Bombardment by magnetospheric particles is consistent with the concentration of dark material and enhanced CO2 absorption on the trailing hemisphere of Dione independent of the geology. Local regions within this terrain indicate a special kind of resurfacing that probably is related to large-scale impact process. In contrast, the enhanced ice signature on the leading side is associated with the extended ejecta of the fresh impact crater Creusa (∼49°N/76°W). Although no geologically active regions could be identified, Dione’s tectonized regions observed with high spatial resolution partly show some clean H2O ice implying that tectonic processes could have continued into more recent times. [Copyright &y& Elsevier]

Published

2010

22. Fluvial erosion and post-erosional processes on Titan

Author

Jaumann, Ralf, Brown, Robert H., Stephan, Katrin, Barnes, Jason W., Soderblom, Larry A., Sotin, Christophe, Le Mouélic, Stephané, Clark, Roger N., Soderblom, Jason, Buratti, Bonnie J., Wagner, Roland, McCord, Thomas B., Rodriguez, Sebastien, Baines, Kevin H., Cruikshank, Dale P., Nicholson, Phil D., Griffith, Caitlin A., Langhans, Mirjam, and Lorenz, Ralph D.

Subjects

*EROSION, *POLYWATER, *DETECTORS, *SPECTRUM analysis

Abstract

Abstract: The surface of Titan has been revealed by Cassini observations in the infrared and radar wavelength ranges as well as locally by the Huygens lander instruments. Sand seas, recently discovered lakes, distinct landscapes and dendritic erosion patterns indicate dynamic surface processes. This study focus on erosional and depositional features that can be used to constrain the amount of liquids involved in the erosional process as well as on the compositional characteristics of depositional areas. Fluvial erosion channels on Titan as identified at the Huygens landing site and in RADAR and Visible and Infrared Mapping Spectrometer (VIMS) observations have been compared to analogous channel widths on Earth yielding average discharges of up to 1600 m3/s for short recurrence intervals that are sufficient to move centimeter-sized sediment and significantly higher discharges for long intervals. With respect to the associated drainage areas, this roughly translates to 1–150 cm/day runoff production rates with 10 years recurrence intervals and by assuming precipitation this implies 0.6–60 mm/h rainfall rates. Thus the observed surface erosion fits with the methane convective storm models as well as with the rates needed to transport sediment. During Cassini''s T20 fly-by, the VIMS observed an extremely eroded area at 30° W, 7° S with resolutions of up to 500 m/pixel that extends over thousands of square kilometers. The spectral characteristics of this area change systematically, reflecting continuous compositional and/or particle size variations indicative of transported sediment settling out while flow capacities cease. To account for the estimated runoff production and widespread alluvial deposits of fine-grained material, release of area-dependent large fluid volumes are required. Only frequent storms with heavy rainfall or cryovolcanic induced melting can explain these erosional features. [Copyright &y& Elsevier]

Published

2008

23. Compositional mapping of Saturn's satellite Dione with Cassini VIMS and implications of dark material in the Saturn system

Author

Clark, Roger N., Curchin, John M., Jaumann, Ralf, Cruikshank, Dale P., Brown, Robert H., Hoefen, Todd M., Stephan, Katrin, Moore, Jeffrey M., Buratti, Bonnie J., Baines, Kevin H., Nicholson, Philip D., and Nelson, Robert M.

Subjects

*SATELLITES of Saturn, *SPECTRUM analysis, *PHOEBE (Satellite)

Abstract

Abstract: Cassini VIMS has obtained spatially resolved imaging spectroscopy data on numerous satellites of Saturn. A very close fly-by of Dione provided key information for solving the riddle of the origin of the dark material in the Saturn system. The Dione VIMS data show a pattern of bombardment of fine, sub-0.5-μm diameter particles impacting the satellite from the trailing side direction. Multiple lines of evidence point to an external origin for the dark material on Dione, including the global spatial pattern of dark material, local patterns including crater and cliff walls shielding implantation on slopes facing away from the trailing side, exposing clean ice, and slopes facing the trailing direction which show higher abundances of dark material. Multiple spectral features of the dark material match those seen on Phoebe, Iapetus, Hyperion, Epimetheus and the F-ring, implying the material has a common composition throughout the Saturn system. However, the exact composition of the dark material remains a mystery, except that bound water and, tentatively, ammonia are detected, and there is evidence both for and against cyanide compounds. Exact identification of composition requires additional laboratory work. A blue scattering peak with a strong UV–visible absorption is observed in spectra of all satellites which contain dark material, and the cause is Rayleigh scattering, again pointing to a common origin. The Rayleigh scattering effect is confirmed with laboratory experiments using ice and 0.2-μm diameter carbon grains when the carbon abundance is less than about 2% by weight. Rayleigh scattering in solids is also confirmed in naturally occurring terrestrial rocks, and in previously published reflectance studies. The spatial pattern, Rayleigh scattering effect, and spectral properties argue that the dark material is only a thin coating on Dione''s surface, and by extension is only a thin coating on Phoebe, Hyperion, and Iapetus, although the dark material abundance appears higher on Iapetus, and may be locally thick. As previously concluded for Phoebe, the dark material appears to be external to the Saturn system and may be cometary in origin. We also report a possible detection of material around Dione which may indicate Dione is active and contributes material to the E-ring, but this observation must be confirmed. [Copyright &y& Elsevier]

Published

2008

24. Laboratory experiments of Titan tholin formed in cold plasma at various pressures: implications for nitrogen-containing polycyclic aromatic compounds in Titan haze

Author

Imanaka, Hiroshi, Khare, Bishun N., Elsila, Jamie E., Bakes, Emma L.O., McKay, Christopher P., Cruikshank, Dale P., Sugita, Seiji, Matsui, Takafumi, and Zare, Richard N.

Subjects

*HAZE, *TITAN (Satellite), *SPECTRUM analysis, *ORGANIC chemistry

Abstract

Titan, the largest satellite of Saturn, has a thick nitrogen/methane atmosphere with a thick global organic haze. A laboratory analogue of Titan''s haze, called tholin, was formed in an inductively coupled plasma from nitrogen/methane=90/10 gas mixture at various pressures ranging from 13 to 2300 Pa. Chemical and optical properties of the resulting tholin depend on the deposition pressure in cold plasma. Structural analyses by IR and UV/VIS spectroscopy, microprobe laser desorption/ionization mass spectrometry, and Raman spectroscopy suggest that larger amounts of aromatic ring structures with larger cluster size are formed at lower pressures (13 and 26 Pa) than at higher pressures (160 and 2300 Pa). Nitrogen is more likely to incorporate into carbon networks in tholins formed at lower pressures, while nitrogen is bonded as terminal groups at higher pressures. Elemental analysis reveals that the carbon/nitrogen ratio in tholins increases from 1.5–2 at lower pressures to 3 at 2300 Pa. The increase in the aromatic compounds and the decrease in C/N ratio in tholin formed at low pressures indicate the presence of the nitrogen-containing polycyclic aromatic compounds in tholin formed at low pressures. Tholin formed at high pressure (2300 Pa) consists of a polymer-like branched chain structure terminated with &z.sbnd;CH3, &z.sbnd;NH2, and &z.sbnd;C&z.tbnd;N with few aromatic compounds. Reddish-brown tholin films formed at low pressures (13–26 Pa) shows stronger absorptions (almost 10 times larger k-value) in the UV/VIS range than the yellowish tholin films formed at high pressures (160 and 2300 Pa). The tholins formed at low pressures may be better representations of Titan''s haze than those formed at high pressures, because the optical properties of tholin formed at low pressures agree well with that of Khare et al. (1984a, Icarus 60, 127–137), which have been shown to account for Titan''s observed geometric albedo. Thus, the nitrogen-containing polycyclic aromatic compounds we find in tholin formed at low pressure may be present in Titan''s haze. These aromatic compounds may have a significant influence on the thermal structure and complex organic chemistry in Titan''s atmosphere, because they are efficient absorbers of UV radiation and efficient charge exchange intermediaries. Our results also indicate that the haze layers at various altitudes might have different chemical and optical properties. [Copyright &y& Elsevier]

Published

2004