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102. PLANETARY SCIENCE: The geology of Pluto and Charon through the eyes of New Horizons

Author

Moore, Jeffrey M., McKinnon, William B., Spencer, John R., Howard, Alan D., Schenk, Paul M., Beyer, Ross A., Nimmo, Francis, Singer, Kelsi N., Umurhan, Orkan M., White, Oliver L., Stern, Alan S., Ennico, Kimberly, Olkin, Cathy B., Weaver, Harold A., Young, Leslie A., Binzel, Richard P., Buie, Marc W., Buratti, Bonnie J., Cheng, Andrew F., Cruikshank, Dale P., Grundy, Will M., Linscott, Ivan R., Reitsema, Harold J., Reuter, Dennis C., Showalter, Mark R., Bray, Veronica J., Chavez, Carrie L., Howett, Carly J.A., Lauer, Tod R., Lisse, Carey M., Parker, Alex Harrison, Porter, S. B., Robbins, Stuart J., Runyon, Kirby, Stryk, Ted, Throop, Henry B., Tsang, Constantine C.C., Verbiscer, Anne J., Zangari, Amanda M., Chaikin, Andrew L., Wilhelms, Don E., and Science Team, New Horizons

Published
2016
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105. VIMS spectral mapping observations of Titan during the Cassini prime mission

Author

Barnes, Jason W., Soderblom, Jason M., Brown, Robert H., Buratti, Bonnie J., Sotin, Christophe, Baines, Kevin H., Clark, Roger N., Jaumann, Ralf, McCord, Thomas B., Nelson, Robert, Le Mouélic, Stéphane, Rodriguez, Sebastien, Griffith, Caitlin, Penteado, Paulo, Tosi, Federico, Pitman, Karly M., Soderblom, Laurence, Stephan, Katrin, Hayne, Paul, Vixie, Graham, Bibring, Jean-Pierre, Bellucci, Giancarlo, Capaccioni, Fabrizio, Cerroni, Priscilla, Coradini, Angioletta, Cruikshank, Dale P., Drossart, Pierre, Formisano, Vittorio, Langevin, Yves, Matson, Dennis L., Nicholson, Phillip D., and Sicardy, Bruno

Published
2009
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107. Ices on the Surface of Triton

Author

Cruikshank, Dale P., Roush, Ted L., Owen, Tobias C., Geballe, Thomas R., de Bergh, Catherine, Schmitt, Bernard, Brown, Robert H., and Bartholomew, Mary Jane

Published
1993

108. Surface Ices and the Atmospheric Composition of Pluto

Author

Owen, Tobias C., Roush, Ted L., Cruikshank, Dale P., Elliot, James L., Young, Leslie A., de Bergh, Catherine, Schmitt, Bernard, Geballe, Thomas R., Brown, Robert H., and Bartholomew, Mary Jane

Published
1993

109. PAHs in the Ices of Saturn's Satellites: Connections to the Solar Nebula and the Interstellar Medium

Author

Cruikshank, Dale P and Pendleton, Yvonne J

Subjects
Astrophysics
Abstract

Aliphatic hydrocarbons and PAHs have been observed in the interstellar medium (e.g., Allamandola et al. 1985, Pendleton et al. 1994, Pendleton & Allamandola 2002, Tielens 2013, Kwok 2008, Chiar & Pendleton 2008) The inventory of organic material in the ISM was likely incorporated into the molecular cloud in which the solar nebula condensed, contributing to the feedstock for the formation of the Sun, major planets, and the smaller icy bodies in the region outside Neptune's orbit (transneptunian objects, or TNOs). Additional organic synthesis occurred in the solar nebula (Ciesla & Sandford 2012). Saturn's satellites Phoebe, Iapetus, and Hyperion open a window to the composition of one class of TNO as revealed by the near-infrared mapping spectrometer (VIMS) on the Cassini spacecraft at Saturn. Phoebe (mean diameter 213 km) is a former TNO now orbiting Saturn (Johnson & Lunine 2005). VIMS spectral maps of Phoebe's surface reveal a complex organic spectral signature consisting of prominent aromatic (CH) and aliphatic hydrocarbon (=CH2, -CH3) absorption bands (3.2-3.6 micrometers). Phoebe is the source of a huge debris ring encircling Saturn, and from which particles ((is) approximately 5-20 micrometers size) spiral inward toward Saturn (Verbiscer et al. 2009). They encounter Iapetus and Hyperion where they mix with and blanket the native H2O ice of those two bodies. Quantitative analysis of the hydrocarbon bands on Iapetus demonstrates that aromatic CH is approximately 10 times as abundant as aliphatic CH2+CH3, significantly exceeding the strength of the aromatic signature in interplanetary dust particles, comet particles, and in carbonaceous meteorites (Cruikshank et al. 2014). A similar excess of aromatics over aliphatics is seen in the qualitative analysis of Hyperion and Phoebe itself (Dalle Ore et al. 2012). The Iapetus aliphatic hydrocarbons show CH2/CH3 (is) approximately 4, which is larger than the value found in the diffuse ISM ((is) approximately 2-2.5). Insofar as Phoebe is a primitive body that formed in the outer regions of the solar nebula and has preserved some of the original nebula inventory, it can be key in understanding the content and degree of processing of that nebular material. A dynamical subset of TNOs define the Kuiper Belt, from which the short-period comets originate. Particles collected from comet 81P/Wild contain PAHs with an interstellar signature of deuterium. By inference, the PAHs contained in Phoebe and now dusted on the surfaces of two other Saturn satellites share that interstellar origin. There are other Phoebe-like TNOs that are presently beyond our ability to study in the organic spectral region, but JWST will open that possibility for a number of objects.

Published
2015

110. Stress-activated electric currents in icy planetary bodies : H2O2-doped H2O ices

Author

Freund, Friedemann T., Sornette, Jaufray, Stockburger, Corey, Keller, Cary T., Gray, Amber, Cruikshank, Dale P., Freund, Friedemann T., Sornette, Jaufray, Stockburger, Corey, Keller, Cary T., Gray, Amber, and Cruikshank, Dale P.

Abstract

Planetary satellites such as the Jovian moon Europa and several Kuiper Belt objects (including Pluto) have surfaces consisting largely of H2O ice, which is brittle and behaves as a rock at the low temperatures that prevail in the outer Solar System. Several of those ice-crusted bodies show evidence of tectonic activity indicating high levels of stress. This paper reports on laboratory experiments with pure H2O ice and H2O2–doped H2O ices with H2O2 concentration levels comparable to those in the ices of Europa. Elongated rectangular ice blocks at T = −81 °C [192 K] were stressed at one end to test whether electric currents are generated and capable of flowing down the stress gradient. Pure H2O ice was found to not produce currents above the 10−10 A background level except for occasional transients in the 10−9–10−8 A range during fracture or rapid plastic deformation due to electrons, e’. By contrast, stressing H2O2-doped H2O ices consistently produced electric currents in the 10−7–10−5 A range, due to holes, h•, propagating from the stressed end to the unstressed end. The h• charge carriers are generated by the break-up of peroxy bonds of H2O2 molecules, leading to O−, equivalent to defect electrons or holes h• in the O2− matrix. © 2020, The work has been supported by the NASA Exobiology grant NNX10AR81G and the NASA Earth Surface and Interior grant NNX12AL71G , both to FTF. AG was supported through the NASA Earth Surface and Interior grant NNX12AL71G to FTF.

Published
2021
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112. Eclipse reappearances of Io: Time-resolved spectroscopy (1.9-4.2[mu]m)

Author

Cruikshank, Dale P., Emery, Joshua P., Kornei, Katherine A., Bellucci, Giancarlo, and D'Aversa, Emiliano

Subjects
Astronomy, Spectrum analysis, Astronomy, Earth sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.icarus.2009.05.035 Byline: Dale P. Cruikshank (a), Joshua P. Emery (b), Katherine A. Kornei (c), Giancarlo Bellucci (d), Emiliano d'Aversa (d) Keywords: Io; Ices; IR spectroscopy; Satellites; Surfaces Abstract: We obtained time-resolved, near-infrared spectra of Io during the 60-90min following its reappearance from eclipse by Jupiter on five occasions in 2004. The purpose was to search for spectral changes, particularly in the well-known SO.sub.2 frost absorption bands, that would indicate surface-atmosphere exchange of gaseous SO.sub.2 induced by temperature changes during eclipse. These observations were a follow-on to eclipse spectroscopy observations in which Bellucci et al. [Bellucci et al., 2004. Icarus 172, 141-148] reported significant changes in the strengths of two strong SO.sub.2 bands in data acquired with the VIMS instrument aboard the Cassini spacecraft. One of the bands (4.07[mu]m [[nu].sub.1 + [nu].sub.3]) observed by Bellucci et al. is visible from ground-based observatories and is included in our data. We detected no changes in Io's spectrum at any of the five observed events during the approximately 60-90min during which spectra were obtained following Io's emergence from Jupiter's shadow. The areas of the three strongest SO.sub.2 bands in the region 3.5-4.15[mu]m were measured for each spectrum; the variation of the band areas with time does not exceed that which can be explained by the Io's few degrees of axial rotation during the intervals of observation, and in no case does the change in band strength approach that seen in the Cassini VIMS data. Our data are of sufficient quality and resolution to show the weak 2.198[mu]m (4549.6cm.sup.-1) 4[nu].sub.1 band of SO.sub.2 frost on Io for what we believe is the first time. At one of the events (June 22, 2004), we began the acquisition of spectra [approximately equal to]6min before Io reappeared from Jupiter's shadow, during which time it was detected through its own thermal emission. No SO.sub.2 bands were superimposed on the purely thermal spectrum on this occasion, suggesting that the upper limit to condensed SO.sub.2 in the vertical column above Io's surface was [approximately equal to]4x10.sup.-5 gcm.sup.-2. Author Affiliation: (a) NASA Ames Research Center, MS 245-6, Moffett Field, CA 94035-1000, USA (b) Dept. of Earth and Planetary Sciences, University of Tennessee, 1412 Circle Dr., Knoxville, TN 37996, USA (c) Dept. of Physics and Astronomy, University of California Los Angeles, Box 951547, Los Angeles, CA 90095, USA (d) INAF-IFSI, Istituto di Fisica dello Spazio Interplanetario, Area Ricerca Tor Vergata, Via Fosso del, Cavaliere 100, I-00133 Roma, Italy Article History: Received 25 September 2006; Revised 28 April 2009; Accepted 1 May 2009

Published
2010
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113. New Horizons: Anticipated Scientific Investigations at the Pluto System

Author

Young, Leslie A., Stern, S. Alan, Weaver, Harold A., Bagenal, Fran, Binzel, Richard P., Buratti, Bonnie, Cheng, Andrew F., Cruikshank, Dale, Gladstone, G. Randall, Grundy, William M., Hinson, David P., Horanyi, Mihaly, Jennings, Donald E., Linscott, Ivan R., McComas, David J., McKinnon, William B., McNutt, Ralph, Moore, Jeffery M., Murchie, Scott, Olkin, Catherine B., Porco, Carolyn C., Reitsema, Harold, Reuter, Dennis C., Spencer, John R., Slater, David C., Strobel, Darrell, Summers, Michael E., and Tyler, G. Leonard

Published
2008
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114. Dione’s Wispy Terrain: A Cryovolcanic Story?

Author

Dalle Ore, Cristina M., primary, Long, Christopher J., additional, Nichols-Fleming, Fiona, additional, Scipioni, Francesca, additional, Rivera Valentín, Edgard G., additional, Lopez Oquendo, Andy J., additional, and Cruikshank, Dale P., additional

Published
2021
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115. Gemini NorthNIRI Spectra of Pluto and Charon: Simultaneous Analysis of the Surface and Atmosphere

Author

Cook, Jason C, Cruikshank, Dale P, and Young, Leslie A

Subjects
Astrophysics
Abstract

94035We report on our analysis of blended Pluto and Charon spectra over the wavelength range 1.4 to 2.5 m as obtained by the NIRI instrument on Gemini North on June 25-28, 2004. The data have a resolving power () around 1500 and a SNR around 200 per pixel. The observed blended spectra are compared to models that combine absorption from the solid ice on the surface using Hapke theory, and absorption from the gaseous atmosphere. We assume the spectrum is a combination of several spatially separate spectral units: a CH4-rich ice unit, a volatile unit (an intimate mixture of N2, CH4 and CO), and a Charon unit (H2O, ammonia hydrate and kaolinite). We test for the presence of hydrocarbons (i.e. C2H6) and nitriles (i.e. HCN) and examine cases where additional ices are present as either pure separate spatial units, mixed with the CH4-rich unit or part of the volatile unit. We conclude that 2-4 of Plutos surface is covered with pure-C2H6 and our identification of C2H6 is significantly strengthened when absorption due to gaseous CH4 is included. The inclusion of Plutos atmosphere demonstrates that low-resolution, high-SNR observations are capable of detecting Plutos atmosphere during a time when Plutos atmosphere may have been undergoing rapid changes (1988-2002) and no high-resolution spectra were obtained. In particular, we identify features at 1.665 and 2.317 m as the Q-branch of the 23 and 3+4 bands of gaseous CH4, respectively. The later band is also evident in many previously published spectra of Pluto. Our analysis finds it is unnecessary to include 13CO to explain the depth of the 2.405 m, which has been previously suggested to be a spectral blended with C2H6, but we cannot definitively rule out its presence. Funding for this work (Cook) has been provided by a NASA-PATM grant.

Published
2014

116. Amorphous and Crystalline H20 Ice at Rhea's Inktomi Crater

Author

Lewis, Emma M, Dalle Ore, Cristina M, Cruikshank, Dale P, and White, Oliver L

Subjects
Lunar And Planetary Science And Exploration
Abstract

We present the analysis of Cassini spectral data from spectral mapping of Saturnian icy moons Dione and Rhea, to investigate possible effects of impact crater formation on the relative abundances of crystalline and amorphous water ice in the moons' ice crusts. Both moons display morphologically young ray craters as well as older craters. Possible changes in ice properties due to crater formation are conjectured to be more visible in younger craters, and as such Rhea's well imaged ray crater Inktomi is analysed, as are older craters for comparison. We used data from Cassini's Visual and Infrared Mapping Spectrometer (VIMS). For each pixel in the VIMS maps, spectral data were extracted in the near-infrared range (1.75 micrometers less than lambda less than 2.45 micrometers). Analysis was begun by fitting a single Gaussian to the peak in absorption at 2.0 micrometers, which was then subtracted from the data, leaving residuals with a minimum on either side of the original 2.0-micrometers band. The spectra of the individual spatial pixels were then clustered by the differences between these minima, which are sensitive to changes in both ice grain size and crystallinity. This yielded preliminary maps which approximated the physical characteristics of the landscape and were used to identify candidates for further analysis. Spectra were then clustered by the properties of the 1.5-micrometers band, to divide the map into regions based on inferred grain size. For each region, the predicted differences in minima from the Gaussian residuals, over a range of crystallinities, were calculated based on the found grain sizes. This model was used to find the crystallinity of each pixel via grain size and characteristics of the residual function. Preliminary results show a greater degree of crystallization of young crater interiors, particularly in Rhea's ray crater Inktomi, where ice showed crystalline ice abundances between 33 percent and 61 percent. These patterns in ice crystallization are possibly attributable to increased heat generated during crater formation.

Published
2014

117. Origins of the Lunar and Planetary Laboratory, University of Arizona

Author

Cruikshank, Dale P and Hartmann, W. K

Subjects
Astronomy
Abstract

The roots of the Lunar and Planetary Laboratory (LPL) extend deep into the rich fabric of G. P. Kuiper's view of the Earth as a planet and planetary systems as expected companions to most stars, as well as the post-war emergent technology of infrared detectors suitable for astronomy. These concepts and events began with Kuiper's theoretical work at Yerkes Observatory on the origin of the Solar System, his discovery of two planetary satellites and observational work with his near-infrared spectrometer on the then-new McDonald 82-inch telescope in the mid- to late-1940s. A grant for the production of a photographic atlas of the Moon in the mid-1950s enabled him to assemble the best existing images of the Moon and acquire new photographs. This brought E. A. Whitaker and D. W. G. Arthur to Yerkes. Others who joined in the lunar work were geologist Carl S. Huzzen and grad student E. P. Moore, as well as undergrad summer students A. B. Binder and D. P. Cruikshank (both in 1958). The Atlas was published in 1959, and work began on an orthographic lunar atlas. Kuiper's view of planetary science as an interdisciplinary enterprise encompassing astronomy, geology, and atmospheric physics inspired his vision of a research institution and an academic curriculum tuned to the combination of all the scientific disciplines embraced in a comprehensive study of the planets. Arrangements were made with the University of Arizona (UA) to establish LPL in affiliation with the widely recognized Inst. of Atmospheric Physics. Kuiper moved to the UA in late 1960, taking the lunar experts, graduate student T. C. Owen (planetary atmospheres), and associate B. M. Middlehurst along. G. van Biesbroeck also joined the migration to Tucson; Binder and Cruikshank followed along as new grad students. Astronomy grad student W. K. Hartmann came into the academic program at UA and the research group at LPL in 1961. Senior faculty affiliating with LPL in the earliest years were T. Gehrels, A. B. Meinel, H. L. Johnson, and F. J. Low, each with their own grad students and associates. Work began on IR spectroscopy and a rectified lunar atlas. Kuiper and Johnson started the search for future observatory sites in N. America and Hawaii.

Published
2014

118. Laboratory Investigations of the Complex Refractory Organic Material Produced from Irradiation of Pluto Ice Analogs

Author

Materese, Christopher K, Cruikshank, Dale P, Sanford, Scott A, and Imanaka, Hiroshi

Subjects
Astrophysics
Abstract

Much of Pluto's surface consists of N2 ice with smaller amounts of CH4 and CO ices. Despite the low temperature (approximately 45K), chemistry can be driven in the surface ices by radiation processing such as cosmic ray bombardment. When cosmic rays strike the surface, much of their energy is dispersed in the form of secondary electrons, which in turn drive much of the resulting chemical reactions. Laboratory experiments designed to simulate the conditions on these icy bodies may provide insight into this chemistry. Significant progress has been made in the laboratory toward understanding the smaller, simple compounds produced in the solid phase by radiation processing of (N2, CH4, CO) ices (Bohn et al. 1994; Moore & Hudson 2003; Hodyss et al. 2011; Kim and Kaiser 2012). Recently Materese et al. (2014) used a variety of techniques to better characterize the refractory materials produced from the UV photo-irradiation of N2:CH4:CO ices. However, because Pluto's atmosphere is optically thick to Lyman-alpha UV radiation it is important to re-examine the results using an alternate radiation source. Our latest work has consisted of the analysis of refractory materials produced from the electron bombardment of low temperature N2(‐), CH4(‐), and CO(‐)containing ices (100:1:1). The ice mixture was chosen to be analogous to the known surface ices on Pluto and the radiation source was chosen to mimic the secondary electrons produced by cosmic rays bombardment. The residues were studied using multiple chemical techniques including, infrared (IR) spectroscopy, X‐ray absorption near‐edge structure (XANES) spectroscopy, and gas chromatography coupled with mass spectrometry (GC‐MS). The organic residues produced in these experiments can be seen as an analog for the refractory component of the surface of Pluto, and are compared with the residues previously obtained from UV photo‐irradiation. UV and near‐ IR spectroscopy of the surfaces of Pluto and Charon during the encounter with NASA's New Horizons spacecraft in 2015, will give the first close‐up measurements of ices and their photoproducts. Laboratory measurements and experiments will provide a better context for the data returned by the spacecraft.

Published
2014

120. Interstellar Organics, the Solar Nebula, and Saturn's Satellite Phoebe

Author

Pendleton, Yvonne J and Cruikshank, Dale P

Subjects
Astrophysics
Abstract

The diffuse interstellar medium inventory of organic material (Pendleton et al. 1994, Pe 2002) was likely incorporated into the molecular cloud in which the solar nebula condensed. This provided the feedstock for the fo planets, and the smaller icy bodies in the region outside Neptune's orbit (transneptunian objects, or TNOs). Saturn's satellites Phoeb open a window to the composition of one class of TNO as revealed by the near-infrared mapping spectrometer (VIMS) on the Cass Phoebe (mean diameter 213 km) is a former TNO now orbiting Saturn. VIMS spectral maps of Phoebe's surface reveal a complex consisting of prominent aromatic (CH) and aliphatic hydrocarbon (CH2, CH3) absorption bands (3.2-3.6 μm). Phoebe is the source encircling Saturn, and from which particles (~5-20 μm size) spiral inward toward Saturn. They encounter Iapetus and Hyperion wh blanket the native H2O ice of those two bodies. Quantitative analysis of the hydrocarbon bands on Iapetus demonstrates that aroma abundant as aliphatic CH2+CH3, significantly exceeding the strength of the aromatic signature in interplanetary dust particles, com carbonaceous meteorites (Cruikshank et al. 2013). A similar excess of aromatics over aliphatics is seen in the qualitative analysis o itself (Dalle Ore et al. 2012). The Iapetus aliphatic hydrocarbons show CH2/CH3 ~4, which is larger than the value found in the di as Phoebe is a primitive body that formed in the outer regions of the solar nebula and has preserved some of the original nebula inv understanding the content and degree of processing of that nebular material. There are other Phoebe-like TNOs that are presently b in the organic spectral region, but JWST will open that possibility for a number of objects. We now need to explore and understand organic-bearing Solar System material to the solar nebula and the inventory of ISM materials incorporated therein.

Published
2014

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

Author

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

Subjects
Submarine boats, Astronomy, Earth sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.icarus.2006.10.010 Byline: Galina M. Chaban, Max Bernstein, Dale P. Cruikshank Keywords: Ices; Infrared observations; Spectroscopy; Jupiter; satellites; Saturn; satellites; Satellites; surfaces Abstract: An absorption band at [approximately equal to]4.26[mu]m wavelength attributed to the asymmetric stretching mode of CO in CO.sub.2 has been found on two satellites of Jupiter and several satellites of Saturn. The wavelength of pure CO.sub.2 ice determined in the laboratory is 4.2675 [mu]m, indicating that the CO.sub.2 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.sup.-1. We have performed ab initio quantum chemical calculations of CO.sub.2 molecules chemically complexed with one, two, and more H.sub.2O molecules and molecules of CH.sub.3OH to explore the possibility that the blue shift of the band is caused by chemical complexing of CO.sub.2 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.sup.-1 from pure CO.sub.2 to CO-H.sub.2O, and an additional 5 cm.sup.-1 from CO.sub.2-H.sub.2O to CO.sub.2-2H.sub.2O. Complexing with more than two H.sub.2O molecules does not increase the blue shift. Complexes of CO.sub.2 with one molecule of CH.sub.3OH and with one CH.sub.3OH plus one H.sub.2O molecule produce smaller shifts than the CO.sub.2-2H.sub.2O complex. Laboratory studies of CO.sub.2:H.sub.2O in a solid N.sub.2 matrix also show a blue shift of the asymmetric stretching mode. Author Affiliation: NASA Ames Research Center, Mail Stop T27B-1, Moffett Field, CA 94035-1000, USA Article History: Received 15 August 2006; Revised 10 October 2006

Published
2007

122. Correlations between Cassini VIMS spectra and RADAR SAR images: Implications for Titan's surface composition and the character of the Huygens Probe Landing Site

Author

Soderblom, Laurence A., Kirk, Randolph L., Lunine, Jonathan I., Anderson, Jeffrey A., Baines, Kevin H., Barnes, Jason W., Barrett, Janet M., Brown, Robert H., Buratti, Bonnie J., Clark, Roger N., Cruikshank, Dale P., Elachi, Charles, Janssen, Michael A., Jaumann, Ralf, Karkoschka, Erich, Mouélic, Stéphane Le, Lopes, Rosaly M., Lorenz, Ralph D., McCord, Thomas B., Nicholson, Philip D., Radebaugh, Jani, Rizk, Bashar, Sotin, Christophe, Stofan, Ellen R., Sucharski, Tracie L., Tomasko, Martin G., and Wall, Stephen D.

Published
2007
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123. Near-infrared spectra of laboratory H.sub.2O-CH.sub.4 ice mixtures

Author

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

Subjects
Astronomy, Earth sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.icarus.2005.10.021 Byline: Max P. Bernstein, Dale P. Cruikshank, Scott A. Sandford Keywords: Ices; Infrared observations; Spectroscopy; Surfaces; planets; Surfaces; satellites Abstract: We present 1.25-19 [mu]m infrared spectra of pure solid CH.sub.4 and H.sub.2O/CH.sub.4=87, 20, and 3 solid mixtures at temperatures from 15 to 150 K. We compare and contrast the absorptions of CH.sub.4 in solid H.sub.2O with those of pure CH.sub.4. Changes in selected peak positions, profiles, and relative strength with temperature are presented, and absolute strengths for absorptions of CH.sub.4 in solid H.sub.2O are estimated. Using the two largest ([nu].sub.3+[nu].sub.4) and ([nu].sub.1+[nu].sub.4) near-IR absorptions of CH.sub.4 at 2.324 and 2.377 [mu]m (4303 and 4207 cm.sup.-1), respectively, as examples, we show that peaks of CH.sub.4 in solid H.sub.2O are at slightly shorter wavelength (higher frequency) and broader than those of pure solid CH.sub.4. 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 H.sub.2O are irreversible. It is to be hoped that these observations of changes in the positions, profiles, and relative intensities of CH.sub.4 absorptions with concentration and temperature will be of use in understanding spectra of icy outer Solar System bodies. Author Affiliation: NASA Ames Research Center, MS 245-6, Moffett Field, CA 94035, USA Article History: Received 13 July 2005; Revised 17 October 2005

Published
2006

124. Near-infrared laboratory spectra of solid H.sub.2O/CO.sub.2 and CH.sub.3OH/CO.sub.2 ice mixtures

Author

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

Subjects
Astronomy, Earth sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.icarus.2005.07.009 Byline: Max P. Bernstein, Dale P. Cruikshank, Scott A. Sandford Keywords: Ices; infrared observations; Spectroscopy; Surfaces; planets; satellites Abstract: We present near-IR spectra of solid CO.sub.2 in H.sub.2O and CH.sub.3OH, and find they are significantly different from that of pure solid CO.sub.2. Peaks not present in either pure H.sub.2O or pure CO.sub.2 spectra become evident when the two are mixed. First, the putative theoretically forbidden CO.sub.2 (2[nu].sub.3) overtone near 2.134 [mu]m (4685 cm.sup.-1), that is absent from our spectrum of pure solid CO.sub.2, is prominent in the spectra of H.sub.2O/CO.sub.2=5 and 25 mixtures. Second, a 2.74-[mu]m (3650 cm.sup.-1) dangling OH feature of H.sub.2O (and a potentially related peak at 1.89 [mu]m) appear in the spectra of CO.sub.2-H.sub.2O ice mixtures, but are probably not diagnostic of the presence of CO.sub.2. Other CO.sub.2 peaks display shifts in position and increased width because of intermolecular interactions with H.sub.2O. Warming causes some peak positions and profiles in the spectrum of a H.sub.2O/CO.sub.2=5 mixture to take on the appearance of pure CO.sub.2. Absolute strengths for absorptions of CO.sub.2 in solid H.sub.2O are estimated. Similar results are observed for CO.sub.2 in solid CH.sub.3OH. Since the CO.sub.2 (2[nu].sub.3) overtone near 2.134 [mu]m (4685 cm.sup.-1) is not present in pure CO.sub.2 but prominent in mixtures, it may be a good observational (spectral) indicator of whether solid CO.sub.2 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. Author Affiliation: NASA Ames Research Center, MS 245-6, Moffett Field, CA 94035, USA Article History: Received 4 February 2005; Revised 6 June 2005

Published
2005

125. Compositional maps of Saturn's moon Phoebe from imaging spectroscopy

Author

Clark, Roger N., Brown, Robert H., Jaumann, Ralf, Cruikshank, Dale P., Nelson, Robert M., Buratti, Bonnie J., McCord, Thomas B., Lunine, J., Baines, K. H., Bellucci, G., Bibring, J.-P., Capaccioni, F., Cerroni, P., Coradini, A., Formisano, V., Langevin, Y., Matson, D. L., Mennella, V., Nicholson, P. D., Sicardy, B., Sotin, C., Hoefen, Todd M., Curchin, John M., Hansen, Gary, Hibbits, Karl, and Matz, K.-D.

Subjects
Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Roger N. Clark (corresponding author) [1]; Robert H. Brown [2]; Ralf Jaumann [3]; Dale P. Cruikshank [4]; Robert M. Nelson [5]; Bonnie J. Buratti [5]; Thomas B. McCord [6]; [...]

Published
2005
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126. A spectroscopic study of the surfaces of Saturn's large satellites: [H.sub.2]O 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
Saturn (Planet) -- Discovery and exploration, Astronomy, Earth sciences
Abstract

We present spectra of Saturn's icy satellites Mimas, Enceladus, Tethys, Dione, Rhea, and Hyperion, 1.0-2.5 [micro]m, with data extending to shorter (Mimas and Enceladus) and longer (Rhea and Dione) wavelengths for certain objects. The spectral resolution (R = [lambda]/[DELTA][lambda]) 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 (R = 225 at 3 [micro]m) 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 [H.sub.2]O ice at 1.65 [micro]m. We model the leading hemisphere of Rhea in the wavelength range 0.3-3.6 [micro]m 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 [H.sub.2]O 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 [micro]m. 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 C[O.sub.2] (a few weight percent, depending on particle size and mixing), C[H.sub.4] (same), and N[H.sub.4]OH (0.5 weight percent) in our globally averaged spectra of Rhea's leading hemisphere. New laboratory spectral data for N[H.sub.4]OH are presented for the purpose of detection on icy bodies. These limits for C[O.sub.2], C[H.sub.4], and N[H.sub.4]OH 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 [micro]m. Keywords: Ices: Infrared observations: Satellites of Saturn: Spectroscopy: Surfaces, satellite: Organic chemistry

Published
2005

128. Neptune and Triton

Author

Cruikshank, Dale P., Editor, Matthews, M. S., Schumann, A. M., Cruikshank, Dale P., Matthews, M. S., and Schumann, A. M.

Published
2016

129. 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
Titan (Satellite) -- Research, Titan (Satellite) -- Natural history, Astronomy, Earth sciences
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 -C[H.sub.3], -N[H.sub.2], and -C[equivalent to]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. Keywords: Titan; Haze; Tholin; Spectroscopy; Organic chemistry; Nitrogen-containing polycyclic aromatic compounds

Published
2004

130. Analysis of the time-dependent chemical evolution of Titan haze tholin

Author

Khare, Bishun N., Bakes, E.L.O., Imanaka, Hiroshi, McKay, Christopher P., Cruikshank, Dale P., and Arakawa, Edward T.

Subjects
Titan (Satellite), Stratospheric circulation -- Observations, Astronomy, Earth sciences
Abstract

Haze particles exert a significant influence over the thermodynamics and radiation absorption properties of the Titan haze, as well as its complex organic chemistry. Characterization of both the molecular and the submicrometer components of the haze is therefore vital for understanding the global properties of Titan. We have carried out a Titan tholin synthesis experiment and measured the time variation of the infrared spectrum of the product as a thin film developed. Also, to examine the possibility of oxygen contamination, we compared the infrared spectrum of the tholin film with that of a tholin film exposed to dry air and laboratory air. The objective of this study is to understand the chemical processes related to how simple organic molecules are processed into more complex haze particles. The progressive development of features characteristic of amines, aromatic and aliphatic hydrocarbons, and nitriles in the experimental mixture is clear. Of particular interest is the formation of aromatic rings after only a few seconds of glow discharge, indicating that these compounds appear to be intermediates between simple haze molecules and microphysical aerosols. The early dominance of aromatic ring structures is accompanied during the later stages of the experiment by the appearance of nitrile and amine compounds. This time-dependent succession of chemical structures provides vital clues to the possible chemical formation pathways of Titan haze aerosols. Key Words: Titan; tholins; stratospheric chemistry; aromatics; amines; alkanes; hydrocarbons; aerosols.

Published
2002

131. Compositions of the Surfaces of Pluto and its Satellites

Author

Cruikshank, Dale P

Subjects
Lunar And Planetary Science And Exploration
Abstract

The information we have on the chemical compositions of the surfaces of Pluto and Charon has been obtained from Earth-based near-infrared spectroscopy. These bodies are seen in diffusely scattered sunlight upon which absorption bands diagnostic of specific ices are superimposed. Identified so far on Pluto are molecular nitrogen (N2), methane (CH4), carbon monoxide (CO), and ethane (C2H6), all in the frozen state. Charon has the clear spectral signature of H2O ice in the crystalline phase, plus an absorption band near 2.2 microns identified as a hydrated form of NH3. No diagnostic spectra of Pluto's other satellites are currently available. A fraction of Pluto's CH4 is dissolved in solid N2, which is in the hexagonal beta-phase. When a small concentration of CH4 exists in a N2 crystalline matrix, its absorption bands are shifted in wavelength by a small but detectable amount. Indeed the shifting of the CH4 bands is diagnostic of a host matrix. In the case of Pluto, the N2 band (2.148 microns) itself is detected, but for other trans-Neptunian objects where the N2 band cannot be seen, the shifted CH4 bands demonstrate the presence of N2 or (less likely) some other spectrally neutral and transparent matrix material (e.g., Ar). The absence of detectable CO2 and H2O ices on Pluto, while they are clearly present on the otherwise very similar Triton, is noteworthy. The ices of Pluto distributed non-uniformly across its surface, and the distribution shows long-term (decadal) changes. Both seasonal and secular changes may be occurring through transport across the surface as a result of changing temperature, and by seasonal changes in the vapor pressure equilibrium of the ice with the tenuous and variable atmosphere. Models of the photochemistry of the surface ices and the atmosphere of Pluto predict the presence of several materials not yet detected; the most abundant photoproducts are expected to be C2H2, C4H2, HCN, C2H6; HCN has been detected on Triton. Both Pluto and Charon have surface components in addition to the detected ices. These materials of presently unknown composition serve to reduce the albedos of both bodies below that expected for pure ices, and in the case of Pluto impart a yellow-brown coloration; the color of Charon is more nearly neutral. It is generally thought that the non-ice components are more refractory than the ices and that they may be complex carbonaceous materials derived from the ultraviolet and charged particle processing of the surface ices. Minerals are also plausible candidates for the non-ice fraction. The refractory colored components may constitute bedrock upon which variable amounts of the ices are alternately deposited and evaporated as the seasons change. Water ice is expected to be a component of the bedrock, although it has not yet been reliably identified.

Published
2013

132. Search for the 3.4-[micro]m C-H spectral bands on low-albedo asteroids

Author

Cruikshank, Dale P., Geballe, Thomas R., Owen, Tobias C., Dalle Ore, Cristina M., Roush, Ted L., Brown, Robert H., and Lewis, John H.

Subjects
Asteroids -- Analysis, Astronomical research -- Evaluation, Astronomical spectroscopy -- Usage, Infrared spectroscopy -- Usage, Chemistry, Organic -- Usage, Hydrocarbons -- Observations, Astronomy, Earth sciences
Abstract

A report of the detection of the C-H hydrocarbon band complex at 3.4/[micro]m in an asteroid spectrum, by D. P. Cruikshank and R. H. Brown (1987, Science 238, 183-184) is not confirmed by recent data of higher quality. Spectra of the same asteroid and six other low-albedo asteroids do not show this feature, which if present would indicate the presence of hydrocarbons and might link these asteroids with certain classes of carbonaceous meteorites. Key Words: asteroid composition; infrared observations; organic chemistry; spectroscopy; asteroid surfaces.

Published
2002

133. Hydrocarbons on Phoebe, Iapetus, and Hyperion: Quantitative Analysis

Author

Cruikshank, Dale P, MoreauDalleOre, Cristina, Pendleton, Yvonne J, and Clark, Roger Nelson

Subjects
Astrophysics
Abstract

We present a quantitative analysis of the hydrocarbon spectral bands measured on three of Saturn's satellites, Phoebe, Iaperus, and Hyperion. These bands, measured with the Cassini Visible-Infrared Mapping Spectrometer on close fly-by's of these satellites, are the C-H stretching modes of aromatic hydrocarbons at approximately 3.28 micrometers (approximately 3050 per centimeter), and the are four blended bands of aliphatic -CH2- and -CH3 in the range approximately 3.36-3.52 micrometers (approximately 2980- 2840 per centimeter) bably indicating the presence of polycyclic aromatic hydrocarbons (PAH), is unusually strong in comparison to the aliphatic bands, resulting in a unique signarure among Solar System bodies measured so far, and as such offers a means of comparison among the three satellites. The ratio of the C-H bands in aromatic molecules to those in aliphatic molecules in the surface materials of Phoebe, NAro:NAliph approximately 24; for Hyperion the value is approximately 12, while laperus shows an intermediate value. In view of the trend of the evolution (dehydrogenation by heat and radiation) of aliphatic complexes toward more compact molecules and eventually to aromatics, the relative abundances of aliphatic -CH2- and -CH3- is an indication of the lengths of the molecular chain structures, hence the degree of modification of the original material. We derive CH2:CH3 approximately 2.2 in the spectrum of low-albedo material on laperus; this value is the same within measurement errors to the ratio in the diffuse interstellar medium. The similarity in the spectral signatures of the three satellites, plus the apparent weak trend of aromatic/aliphatic abundance from Phoebe to Hyperion, is consistent with, and effectively confirms that the source of the hydrocarbon-bearing material is Phoebe, and that the appearance of that material on the other two satellites arises from the deposition of the inward-spiraling dust that populates the Phoebe ring.

Published
2012

134. Constraints on the composition of Trojan asteroid 624 Hektor

Author

Cruikshank, Dale P., Dalle Ore, Cristina M., Roush, Ted L., Geballe, Thomas R., Owen, Tobias C., de Bergh, Catherine, Cash, Michele D., and Hartmann, William K.

Subjects
Asteroids -- Models, Astrogeology -- Research, Astronomy, Earth sciences
Abstract

We present a composite spectrum of Trojan asteroid 624 Hektor, 0.3-3.6 [micro]m, and models computed for the full wavelength range with the Hapke scattering theory. The data show that there is no discernible 3-[micro]m absorption band. Such a band would indicate the presence of OH- or [H.sub.2]O-bearing silicate minerals, or macromolecular carbon-rich organic material of the kind seen on the low-albedo hemisphere of Saturn's satellite Iapetus. The absence of spectral structure is itself indicative of the absence of the nitrogen-rich tholins (which show a distinctive absorption band attributed to N-H). The successful models in this study all incorporate magnesium-rich pyroxene (Mg, Fe Si[O.sub.3]), which satisfactorily matches the red color of Hektor. Pyroxene is a mafic mineral common in terrestrial and lunar lavas, and is also identified in Main Belt asteroid spectra. An upper limit to the amount of crystalline [H.sub.2]O ice (30-[micro]m grains) in the surface layer of Hektor accessible to near-infrared remote sensing observations is 3 wt%. The upper limit for serpentine, as a representative of hydrous silicates, is much less stringent, at 40%, based on the shape of the spectral region around 3 [micro]m. Thus, the spectrum at 3 [micro]m does not preclude the presence of a few weight percent of volatile material in the uppermost surface layer of Hektor. Below this 'optical' surface that our observations probe, any amount of [H.sub.2]O ice and other volatile-rich materials might exist. All of the models we calculated require a very low-albedo, neutral color material to achieve the low geometric albedo that matches Hektor; we use elemental carbon. If elemental carbon is present on Hektor, it could be of organic or inorganic origin. By analogy, other D-type asteroids could achieve their red color, low albedo, and apparent absence of phyllosilicates from compositions similar to the models

Published
2001

138. Disk-resolved Photometric Properties of Pluto and the Coloring Materials across its Surface

Author

Protopapa, Silvia, primary, Olkin, Cathy B., additional, Grundy, Will M., additional, Li, Jian-Yang, additional, Verbiscer, Anne, additional, Cruikshank, Dale P., additional, Gautier, Thomas, additional, Quirico, Eric, additional, Cook, Jason C., additional, Reuter, Dennis, additional, Howett, Carly J. A., additional, Stern, Alan, additional, Beyer, Ross A., additional, Porter, Simon, additional, Young, Leslie A., additional, Weaver, Hal A., additional, Ennico, Kim, additional, Dalle Ore, Cristina M., additional, Scipioni, Francesca, additional, and Singer, Kelsi, additional

Published
2020
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140. Mimas: Preliminary Evidence For Amorphous Water Ice from VIMS

Author

Cruikshank, Dale P, Marzo, G. A, Pinilla-Alonso, N, Roush, T. L, Mastrapa, R. M, DalleOre, C. M, Buratti, B. J, and Stephan, K

Subjects
Geophysics
Abstract

We have conducted a statistical clustering analysis (1,2) on a mosaic of VIMS data cubes obtained on February 13, 2010, for Saturn s satellite Mimas. Seven VIMS cubes were geometrically projected and re-sampled to a common spatial resolution. The clustering technique consists of a partitioning algorithm coupled to a criterion that prevents sub-optimal solutions and tests for the influence of random noise in the measurements. The clustering technique is agnostic about the meaning of the clusters, and scientific interpretation requires their a posteriori evaluation. The preliminary results yielded five clusters, demonstrating that spectral variability across Mimas surface is statistically significant. The ratios of the means calculated for each of the clusters show structure within the 1.6- micron water ice band, as well as the shape and the central wavelength of the strong ice band at 2 micron, that map spatially in patterns apparently related to the topography of Mimas, in particular certain regions in and around Herschel crater. The mean spectra of the five clusters, show similarities with laboratory spectra of amorphous and crystalline H2O ice (3) that are suggestive of the presence of an amorphous ice component in certain regions of Mimas, notably on the central peak of Herschel, on the crater floor, and in faults surrounding the crater. This may represent a mixture of both ice phases, or perhaps a layer of amorphous ice on a base of crystalline ice. Another possible occurrence of amorphous ice appears southwest of Herschel, close to the south pole.

Published
2010

141. Hydrocarbons on the Icy Satellites of Saturn

Author

Cruikshank, Dale P

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Visible-Infrared Mapping Spectrometer on the Cassini Spacecraft has obtained spectral reflectance maps of the satellites of Saturn in the wavelength region 0.4-5.1 micrometers since its insertion into Saturn orbit in late 2004. We have detected the spectral signature of the C-H stretching molecular mode of aromatic and aliphatic hydrocarbons in the low albedo material covering parts of several of Saturn's satellites, notably Iapetus and Phoebe (Cruikshank et al. 2008). The distribution of this material is complex, and in the case of Iapetus we are seeking to determine if it is related to the native grey-colored materials left as lag deposits upon evaporation of the ices, or represents in-fall from an external source, notably the newly discovered large dust ring originating at Phoebe. This report covers our latest exploration of the nature and source of this organic material.

Published
2010

142. The detection of water ice in comet Hale-Bopp

Author

Davies, John K., Roush, Ted L., Cruikshank, Dale P., Bartholomew, Mary Jane, Geballe, Thomas R., Owen, Tobias, and Bergh, Catherine de

Subjects
Hale-Bopp (Comet) -- Observations, Comets -- Spectra, Astronomy, Earth sciences
Abstract

We present spectra of Comet Hale-Bopp (C/1995 O1) covering the range 1.4-2.5 [[micro]meter] that were recorded when the comet was 7 AU from the Sun. These spectra show broad absorption features at 1.5 and 2.05 [[micro]meter]. While we recognize that much of the light from the comet is scattered from the coma, we show that some, but not all, of the absorption features can be matched by an intimate mixture of water ice and a low-albedo material such as carbon on the nucleus. Furthermore, the absence of the 1.65-[[micro]meter] absorption feature of crystalline ice suggests that the cometary ice was probably in an amorphous state at the time of these observations. An unidentified additional component may be required to account for the downward slope at the long-wavelength end of the spectrum.

Published
1997

145. Complex Organic Materials on Planetary Satellites and Other Small Bodies of the Solar System

Author

Cruikshank, Dale P

Subjects
Astrophysics
Abstract

The search for organic materials on small bodies of the Solar System is conducted spectroscopically from Earth-based telescopes and from spacecraft. Although the carbonaceous meteorites carry a significant inventory of complex organic solids, the sources of these meteorites have not been identified. Infrared spectra of a sample of the suspected sources, the C- and D-class asteroids, including new data from the Spitzer Space Telescope, show signatures of silicates, but none diagnostic of organic compounds. In the absence of discrete spectral features, the low albedos and colors in the visible and near-IR spectral regions are the principal links between the organic-bearing meteorites and the asteroids. While Pluto and a few trans-neptunian objects show spectral signatures of frozen CH4. Solid CH3OH has been identified on two Centaur objects in the outer Solar System. In some cases the red colors of those objects suggest the presence of tholins. The VIMS instrument aboard the Cassini spacecraft in orbit around Saturn has detected near-IR spectral features on at least three of Saturn's satellites that are indicative or suggestive of organic molecules. One entire hemisphere of the satellite Iapetus is covered with low-albedo material that shows a spectral signature of aromatic hydrocarbons (3.3 microns) and the -CH2 stretching mode bands of an aliphatic component. Organics absorbing at 3.44 microns are suspected in the region of the south pole of Enceladus, and also on the surface of Phoebe. Organic material may originate on icy bodies in the current epoch by various processes of energy deposition into native material, or they may fall to the surface from an external (probably cometary) source. Some organic material may be pre-solar, having originated in the interstellar medium before the formation of the Solar System. Using the techniques of remote sensing, its detection and analysis are slow and difficult.

Published
2006

146. Icy Satellites of the Planets, and the Work of V.I. Moroz

Author

Cruikshank, Dale P

Subjects
Lunar And Planetary Science And Exploration
Abstract

The satellites of the giant planets are highly varied in size and density, indicating a wide range of compositions. The principal components of these satellites are ices of many different compositions (with H2O the most abundant) and varying amounts of silicate rocky material. Many different ices have been found by spectroscopic techniques both from Earth-based observatories and from planetary spacecraft. Three of the Galilean satellites of Jupiter exhibit H2O ice on their surfaces, while small amounts of CO2 are present on Ganymede and Callisto. The volcanic satellite Io has abundant SO2 ice and frost deposits. Saturn s satellites have surfaces dominated by H2O ice, but CO2 is also present on most of them, and in the cases of the low-albedo satellites Iapetus and Phoebe, there is evidence of complex hydrocarbons mixed with the surface materials. The large Uranian satellites also have H2O-dominated surfaces, but CO2 has also been discovered on two of them. Neptune s largest satellite, Triton, show spectroscopic evidence for six different ices, including N2, CH4, CO, CO2, H2O, and C2H6. The latter ice is a photochemical product from the action of sunlight on Triton's atmosphere. Pluto is similar to Triton, although CO2 has not been found. Pluto s large satellite, Charon, shows evidence for an ammonia hydrate on part of its surface. V. I. Moroz was a pioneer in the application of near-infrared detectors to astronomical sources. Using a prism spectrometer he measured the spectra of the Galilean satellites of Jupiter, and in 1966 he published the first near-infrared spectra, noting the appearance of H2O ice as a major component of Europa and Ganymede. This discovery, and the techniques of Moroz measurements help set the stage for the broad extension of the study of planetary, satellite, and asteroid surfaces through reflectance spectroscopy in the near-infrared.

Published
2006

147. Tholins as Coloring Agents on Outer Solar System Bodies

Author

Cruikshank, Dale P, Imanaka, Hiroshi, and DalleOre, Cristina M

Subjects
Astronomy
Abstract

The red colors of many solid bodies in outer Solar System may be caused by tholins, which are refractory organic complexes, incorporated in their surface materials. Tholins synthesized in the laboratory are shown to match the colors of these bodies when their optical properties are used in rigorous scattering models. We review recent successes in modeling the spectra of icy outer Solar System bodies with tholins as the coloring agents. New work on the systematic laboratory synthesis and analysis of tholins made by cold plasma discharge in mixtures of gaseous CH4/N2 shows that the composition of the tholin depends strongly on the pressure in the reaction chamber, and only weakly on the mixing fraction of CH4 relative to N2. In tholins made at high pressure (e.g., 23 hPa) the abundance of aliphatic hydrocarbons is greater and the abundance of aromatic hydrocarbons is less than in tholins made at low pressure (e.g., 0.13 hPa). Tholins made at low deposition pressures show a greater abundance of N-H bonds.

Published
2005

148. Solar System Observations with Spitzer Space Telescope: Preliminary Results

Author

Cruikshank, Dale P

Subjects
Lunar And Planetary Science And Exploration
Abstract

The programs of observations of Solar System bodies conducted in the first year of the operation of the Spitzer Space Telescope as part of the Guaranteed Observing Time allocations are described. Initial results include the determination of the albedos of a number of Kuiper Belt objects and Centaurs from observations of their flux densities at 24 and 70 microns, and the detection of emission bands in the spectra of several distant asteroids (Trojans) around 10 and 25 microns. The 10 Kuiper Belt objects observed to date have albedos in the range 0.08 - 0.15, significantly higher than the earlier estimated 0.04. An additional KBO [(55565) 2002 AW(sub l97)] has an albedo of 0.17 plus or minus 0.03. The emission bands in the asteroid spectra are indicative of silicates, but specific minerals have not yet been identified. The Centaur/comet 29P/Schwassmann-Wachmann 1 has a nucleus surface albedo of 0.025 plus or minus 0.01, and its dust production rate was calculated from the properties of the coma. Several other investigations are in progress as the incoming data are processed and analyzed.

Published
2005

149. Temperature of nitrogen ice on Pluto and its implications for flux measurements

Author

Tryka, Kimberly A., Brown, Robert H., Cruikshank, Dale P., Owen, Tobias C., Geballe, Thomas R., and DeBergh, Catherine

Subjects
Pluto (Planet) -- Research, Astronomy, Earth sciences
Abstract

Spectroscopic observations of Pluto reveal that the nitrogen ice on Pluto has a temperature of 40 Kelvin. This is higher than the temperature of nitrogen on the satellite Triton. The study indicates that the nitrogen on the planet is concentrated at the polar caps of the planet and absent in the equatorial region.

Published
1994

150. Spectroscopy of Mars from 2.04 to 2.44 micrometer during the 1993 opposition: absolute calibration and atmospheric vs mineralogic origin of narrow absorption features

Author

Bell, James F., III, Pollack, James B., Geballe, Thomas R., Cruikshank, Dale P., and Freedman, Richard

Subjects
Mars (Planet) -- Spectra, Carbon dioxide -- Research, Solar radiation -- Research, Astronomy, Earth sciences
Abstract

Seven narrow absorption bands are found in the moderate-resolution reflectance spectra of Mars. The reflectance spectra are obtained using the UKIRT 3.8 meter telescope in the 2.04 to 2.44 micrometer region of the seven bands, five of which are produced by the CO2 and CO present in the atmosphere of Mars. The other two bands may be caused by nonatmospheric absorptions and may be due to the reflection of sun's light.

Published
1994

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