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5. The Planetary Data System: A Vital Component in NASA’s Science Exploration Program

Author

Anne C. Raugh, T. McClanahan, Thomas C. Stein, Reta Beebe, Raymond E. Arvidson, E. Grayzeck, Daniel J. Crichton, Myche McAuley, Ray J. Walker, Lisa R. Gaddis, Nancy J. Chanover, Matthew S. Tiscareno, Mark R. Showalter, Sebastien Besse, Louise M. Prockter, Emily Law, Mitchell K. Gordon, Jordan Padams, David M.H. Baker, Trent M. Hare, James Bauer, John S. Hughes, and Charles H. Acton

Subjects
Computer science, Component (UML), Systems engineering, Planetary Data System
Published
2021
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6. A Next Generation Lunar Orbiter Mission

Author

W. R. Patterson, B. W. Denevi, Heather Meyer, Timothy D. Glotch, Kurt D. Retherford, Georgiana Y. Kramer, Lynn M. Carter, S. N. Valencia, Emerson Speyerer, Timothy A. Livengood, A. M. Stickle, Lisa R. Gaddis, Michael J. Poston, Ryan Watkins, B. T. Greenhagen, Pamela Clark, D. P. Moriarty, Harald Hiesinger, Kerri Donaldson Hanna, J. T. S. Cahill, Catherine Elder, Matthew A. Siegler, Lillian R. Ostrach, Noah E. Petro, Carolyn H. van der Bogert, and Morgan Shusterman

Subjects
Lunar orbiter, Environmental science, Astrobiology
Published
2021
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7. Exploring end-member volcanism on the Moon at the Aristarchus Plateau

Author

J. D. Clark, D. H. Needham, Brett W. Denevi, D. P. Moriarty, Sebastien Besse, Lauren Jozwiak, Kristen A. Bennett, Sarah N. Valencia, R. Aileen Yingst, Shashwat Shukla, Erica Jawin, B. L. Jolliff, Timothy D. Glotch, Ryan Watkins, Lisa R. Gaddis, and Heather Meyer

Subjects
Paleontology, geography, Plateau, geography.geographical_feature_category, Volcanism, Geology
Published
2021
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8. On the Use of Planetary Science Data for Studying Extrasolar Planets

Author

Nancy J. Chanover, Jeffrey Jewell, Daniel J. Crichton, Lisa R. Gaddis, L. C. Mayorga, J. Steve Hughes, Mark S. Marley, G. Bryden, Louise M. Prockter, Gael M. Roudier, Mitchell K. Gordon, Mark R. Swain, Robert A. West, T. Joseph W. Lazio, and J. H. Padams

Subjects
Solar System, Data access, Planetary science, Computer science, Physics::Space Physics, Astrophysics::Instrumentation and Methods for Astrophysics, Astrophysics::Solar and Stellar Astrophysics, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Astrophysics::Earth and Planetary Astrophysics, Investment (macroeconomics), GeneralLiterature_MISCELLANEOUS, Exoplanet, Astrobiology
Abstract

There is an opportunity to advance solar system and extrasolar planetary studies that does not require new telescopes or new missions but better use and access to data sets. This approach leverages significant investment from space agencies in exploring the solar system and using those discoveries for the study of extrasolar planets.

Published
2021
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9. Volcanic Processes in the Gassendi Region of the Moon

Author

Julie Stopar, Bruce A. Campbell, C. A. Peterson, Thomas A. Giguere, David T. Blewett, David Trang, Samuel J. Lawrence, J. Olaf Gustafson, Jeffrey J. Gillis-Davis, Myriam Lemelin, Cassandra R. Runyon, B. Ray Hawke, Joseph M. Boyce, and Lisa R. Gaddis

Subjects
geography, Geophysics, geography.geographical_feature_category, Volcano, Space and Planetary Science, Geochemistry and Petrology, Remote sensing (archaeology), Earth science, Earth and Planetary Sciences (miscellaneous), Volcanism, Geology
Published
2020
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10. Revised recommended methods for analyzing crater size-frequency distributions

Author

Stuart J. Robbins, Brian P. Weaver, Clark R. Chapman, E. B. Bierhaus, Kelsi N. Singer, Michelle R. Kirchoff, Jamie D. Riggs, and Lisa R. Gaddis

Subjects
Geophysics, 010504 meteorology & atmospheric sciences, Impact crater, Space and Planetary Science, 0103 physical sciences, Size frequency, 010303 astronomy & astrophysics, 01 natural sciences, Geology, Seismology, 0105 earth and related environmental sciences
Published
2018
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11. Investigation of Lunar Spinels at Sinus Aestuum

Author

Jessica M. Sunshine, M. Staid, S. Besse, Lisa R. Gaddis, and Catherine M. Weitz

Subjects
010504 meteorology & atmospheric sciences, Spinel, Anatomy, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, medicine.anatomical_structure, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), engineering, medicine, Geology, Sinus (anatomy), 0105 earth and related environmental sciences
Published
2017
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12. Maximizing the value of Solar System data through Planetary Spatial Data Infrastructures

Author

David R. Williams, T. Hare, Ross A. Beyer, Louise Prockter, Caleb I. Fassett, Jani Radebaugh, D. N. DellaGiustina, J. Laura, Sarah S. Sutton, Lisa R. Gaddis, Sander Goossens, Pete Mouginis-Mark, Justin J. Hagerty, Alex Patthoff, Brent A. Archinal, Bradley J. Thomson, Julie Stopar, and Andrea Naß

Subjects
Earth and Planetary Astrophysics (astro-ph.EP), Infrastructure, Spatial data infrastructure, Process (engineering), Computer science, FOS: Physical sciences, USable, Planetary Data, Planetary Data System, Data science, Data acquisition, Planetary science, Component (UML), Solar System, Astrophysics - Instrumentation and Methods for Astrophysics, Spatial analysis, Instrumentation and Methods for Astrophysics (astro-ph.IM), Astrophysics - Earth and Planetary Astrophysics
Abstract

Planetary spatial data returned by spacecraft, including images and higher-order products such as mosaics, controlled basemaps, and digital elevation models (DEMs), are of critical importance to NASA, its commercial partners and other space agencies. Planetary spatial data are an essential component of basic scientific research and sustained planetary exploration and operations. The Planetary Data System (PDS) is performing the essential job of archiving and serving these data, mostly in raw or calibrated form, with less support for higher-order, more ready-to-use products. However, many planetary spatial data remain not readily accessible to and/or usable by the general science user because particular skills and tools are necessary to process and interpret them from the raw initial state. There is a critical need for planetary spatial data to be more accessible and usable to researchers and stakeholders. A Planetary Spatial Data Infrastructure (PSDI) is a collection of data, tools, standards, policies, and the people that use and engage with them. A PSDI comprises an overarching support system for planetary spatial data. PSDIs (1) establish effective plans for data acquisition; (2) create and make available higher-order products; and (3) consider long-term planning for correct data acquisition, processing and serving (including funding). We recommend that Planetary Spatial Data Infrastructures be created for all bodies and key regions in the Solar System. NASA, with guidance from the planetary science community, should follow established data format standards to build foundational and framework products and use those to build and apply PDSIs to all bodies. Establishment of PSDIs is critical in the coming decade for several locations under active or imminent exploration, and for all others for future planning and current scientific analysis., Comment: 8 pages, 0 figures. White paper submitted to the Planetary Science and Astrobiology Decadal Survey 2023-2032

Published
2020
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13. Complex explosive volcanic activity on the Moon within Oppenheimer crater

Author

James F. Bell, Benjamin T. Greenhagen, Briony Horgan, Lisa R. Gaddis, Paul O. Hayne, Kristen A. Bennett, David A. Paige, and Carlton C. Allen

Subjects
geography, Vulcanian eruption, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geochemistry, Pyroclastic rock, Astronomy and Astrophysics, 01 natural sciences, Peléan eruption, Strombolian eruption, Volcanic glass, Astrobiology, Volcano, Impact crater, Space and Planetary Science, 0103 physical sciences, Pyroclastic fall, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

Oppenheimer crater is a floor-fractured crater located within the South Pole–Aitken basin on the Moon, and exhibits more than a dozen localized pyroclastic deposits associated with the fractures. Localized pyroclastic volcanism on the Moon is thought to form as a result of intermittently explosive Vulcanian eruptions under low effusion rates, in contrast to the higher-effusion rate, Hawaiian-style fire fountaining inferred to form larger regional deposits. We use Lunar Reconnaissance Orbiter Camera images and Diviner Radiometer mid-infrared data, Chandrayaan-1 orbiter Moon Mineralogy Mapper near-infrared spectra, and Clementine orbiter Ultraviolet/visible camera images to test the hypothesis that the pyroclastic deposits in Oppenheimer crater were emplaced via Vulcanian activity by constraining their composition and mineralogy. Mineralogically, we find that the deposits are variable mixtures of orthopyroxene and minor clinopyroxene sourced from the crater floor, juvenile clinopyroxene, and juvenile iron-rich glass, and that the mineralogy of the pyroclastics varies both across the Oppenheimer deposits as a whole and within individual deposits. We observe similar variability in the inferred iron content of pyroclastic glasses, and note in particular that the northwest deposit, associated with Oppenheimer U crater, contains the most iron-rich volcanic glass thus far identified on the Moon, which could be a useful future resource. We propose that this variability in mineralogy indicates variability in eruption style, and that it cannot be explained by a simple Vulcanian eruption. A Vulcanian eruption should cause significant country rock to be incorporated into the pyroclastic deposit; however, large areas within many of the deposits exhibit spectra consistent with high abundances of juvenile phases and very little floor material. Thus, we propose that at least the most recent portion of these deposits must have erupted via a Strombolian or more continuous fire fountaining eruption, and in some cases may have included an effusive component. These results suggest that localized lunar pyroclastic deposits may have a more complex origin and mode of emplacement than previously thought.

Published
2016
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14. An investigation of potential pyroclastic deposits on the southeast limb of the Moon

Author

J. Olaf Gustafson, James F. Bell, Lisa R. Gaddis, and J. Aaron Gustafson

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Spectral properties, Geochemistry, Pyroclastic rock, Astronomy and Astrophysics, Volcanism, Albedo, 01 natural sciences, Texture (geology), Volcano, Impact crater, Space and Planetary Science, 0103 physical sciences, Magma, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

We investigated the physical and spectral properties of potential dark mantling deposits (PDMDs) previously and newly identified on the SE limb of the Moon, near the craters Humboldt and Petavius. The goals of this investigation were to constrain the composition and mode of emplacement of these poorly studied deposits, to identify interdeposit variations, and to use these results to draw conclusions about regional and subsurface geologic processes. Our investigation involved an assessment of both the physical properties (size, texture, morphology) and spectral properties (albedo, absorption bands, color ratios) utilizing remote sensing data from multiple lunar orbital missions. We found that many of the SE Limb deposits previously identified as possibly pyroclastic in origin were likely effusively emplaced. However, we also identified several likely pyroclastic deposits, including three not previously mapped. We found that the volcanic deposits across the study area comprise three major spectral groups: one similar to Mare Fecunditatis, one similar to Mare Australe, and one similar to known glassy pyroclastic deposits elsewhere on the Moon. We conclude that volcanism across the SE limb was likely fed from at least two distinct magma source regions, and that the type and extent of surface expression of this volcanic activity was possibly influenced by regional variations in crustal thickness. Our documentation and analysis of the complex volcanic history in this region of the Moon supports ongoing efforts to develop increasingly detailed interpretations of the volcanic history of the entire Moon.

Published
2020
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15. Examining spectral variations in localized lunar dark mantle deposits

Author

Sebastien Besse, S. Mazrouei, James W. Head, Lisa R. Gaddis, Erica Jawin, and Jessica M. Sunshine

Subjects
Basalt, geography, geography.geographical_feature_category, Vulcanian eruption, Mineralogy, Geophysics, Mantle (geology), Spectral line, Volcanic glass, Volcano, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mafic, Geology
Abstract

The localized lunar dark mantle deposits (DMDs) in Alphonsus, J. Herschel, and Oppenheimer craters were analyzed using visible-near-infrared spectroscopy data from the Moon Mineralogy Mapper. Spectra of these localized DMDs were analyzed for compositional and mineralogical variations within the deposits and were compared with nearby mare basalt units. Spectra of the three localized DMDs exhibited mafic absorption features indicating iron-rich compositions, although the DMDs were spectrally distinct from nearby mare basalts. All of the DMDs contained spectral signatures of glassy materials, suggesting the presence of volcanic glass in varying concentrations across the individual deposits. In addition, the albedo and spectral signatures were variable within the Alphonsus and Oppenheimer crater DMDs, suggesting variable deposit thickness and/or variations in the amount of mixing with the local substrate. Two previously unidentified localized DMDs were discovered to the northeast of Oppenheimer crater. The identification of high concentrations of volcanic glass in multiple localized DMDs in different locations suggests that the distribution of volcanic glass across the lunar surface is much more widespread than has been previously documented. The presence of volcanic glass implies an explosive, vulcanian eruption style for localized DMDs, as this allows volcanic glass to rapidly quench, inhibiting crystallization, compared to the larger hawaiian-style eruptions typical of regional DMD emplacement where black beads indicate a higher degree of crystallization. Improved understanding of the local and global distributions of volcanic glass in lunar DMDs will further constrain lunar degassing and compositional evolution throughout lunar volcanic history.

Published
2015
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17. Towards a Planetary Spatial Data Infrastructure

Author

Robin L. Fergason, T. Hare, Jason Laura, Lisa R. Gaddis, Justin J. Hagerty, James A. Skinner, and Brent A. Archinal

Subjects
Spatial data infrastructure, 010504 meteorology & atmospheric sciences, Geography, Planning and Development, Linkage (mechanical), computer.software_genre, spatial data infrastructure, cyberinfrastructure, planetary science, 01 natural sciences, Data science, GeneralLiterature_MISCELLANEOUS, law.invention, Geography, Planetary science, Cyberinfrastructure, law, Planet, Research community, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Data mining, Computers in Earth Sciences, 010303 astronomy & astrophysics, Spatial analysis, computer, 0105 earth and related environmental sciences
Abstract

Planetary science is the study of planets, moons, irregular bodies such as asteroids and the processes that create and modify them. Like terrestrial sciences, planetary science research is heavily dependent on collecting, processing and archiving large quantities of spatial data to support a range of activities. To address the complexity of storing, discovering, accessing, and utilizing spatial data, the terrestrial research community has developed conceptual Spatial Data Infrastructure (SDI) models and cyberinfrastructures. The needs that these systems seek to address for terrestrial spatial data users are similar to the needs of the planetary science community: spatial data should just work for the non-spatial expert. Here we discuss a path towards a Planetary Spatial Data Infrastructure (PSDI) solution that fulfills this primary need. We first explore the linkage between SDI models and cyberinfrastructures, then describe the gaps in current PSDI concepts, and discuss the overlap between terrestrial SDIs and a new, conceptual PSDI that best serves the needs of the planetary science community.

Published
2017
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18. Improving the geometry of Kaguya extended mission data through refined orbit determination using laser altimetry

Author

Brent A. Archinal, Yoshiaki Ishihara, Sander Goossens, Erwan Mazarico, and Lisa R. Gaddis

Subjects
Kaguya, 010504 meteorology & atmospheric sciences, 01 natural sciences, Article, Physics::Geophysics, law.invention, Orbiter, law, 0103 physical sciences, Altimeter, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Spacecraft, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Geodetic datum, Astronomy and Astrophysics, Geodesy, Data set, Space and Planetary Science, Physics::Space Physics, Orbit (dynamics), Astrophysics::Earth and Planetary Astrophysics, Orbit determination, business, Geology
Abstract

The Japan Aerospace Exploration Agency’s (JAXA) Kaguya spacecraft carried a suite of instruments to map the Moon and its environment globally. During its extended mission, the average altitude was 50 km or lower, and Kaguya science products using these data hence have an increased spatial resolution. However, the geodetic position quality of these products is much worse than that of those acquired during the primary mission (at an altitude of 100 km) because of reduced radiometric tracking and frequent thrusting to maintain spacecraft attitude after the loss of momentum wheels. We have analyzed the Kaguya tracking data using gravity models based on the Gravity Recovery and Interior Laboratory (GRAIL) mission, and by making use of a new data type based on laser altimeter data collected by Kaguya: we adjust the spacecraft orbit such that the altimetry tracks fit a precise topographic basemap based on the Lunar Reconnaissance Orbiter’s (LRO) Lunar Orbiter Laser Altimeter (LOLA) data. This results in geodetically accurate orbits tied to the precise LOLA/LRO frame. Whereas previously archived orbits show errors at the level of several kilometers, the inclusion of altimetry greatly improves the orbit precision, to a level of several tens of meters. When altimetry data are not available, the combination of GRAIL gravity and radio tracking results in an orbit precision of around several hundreds of meters for the low-altitude phase of the extended mission. Our greatly improved orbits result in better geolocation of the Kaguya extended mission data set.

Published
2020
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19. Hematite-bearing materials surrounding Candor Mensa in Candor Chasma, Mars: Implications for hematite origin and post-emplacement modification

Author

Robin L. Fergason, Lisa R. Gaddis, and A. D. Rogers

Subjects
Canyon, geography, geography.geographical_feature_category, Lithology, Geochemistry, Astronomy and Astrophysics, Context (language use), Mars Exploration Program, Hematite, Lag deposit, Space and Planetary Science, visual_art, visual_art.visual_art_medium, Aeolian processes, Sulfate minerals, Geology
Abstract

The Valles Marineris canyon system on Mars is of enduring scientific interest in part due to the presence of interior mounds that contain extensive layering and water-altered minerals, such as crystalline gray hematite and hydrated sulfates. The presence of hematite and hydrated sulfate minerals is important because their host rock lithologies provide information about past environments that may have supported liquid water and may have been habitable. This work further defines the association and relationship between hematite-bearing materials and low albedo (presumably aeolian) deposits and layered materials, identifies physical characteristics that are strongly correlated with the presence of hematite, and refines hypotheses for the origin and post-emplacement modification (including transport) of these hematite-bearing and associated materials. There are only three regions surrounding Candor Mensa where hematite has been identified, even though morphologic properties are similar throughout the entire mensa. Three possible explanations for why hematite is only exposed in these regions include: (1) the topographic structure of the mensa walls concentrates hematite at the base of the layered deposits, influencing the ability to detect hematite from orbit; (2) the presence of differing amounts of “dark mantling material” and hematite-free erosional sediment; (3) the potential fracturing of the mensa and the influence of these structures on fluid flow and subsequent digenesis. The observations of hematite-bearing materials in this work support the hypothesis that hematite is eroding from a unit in the Candor Mensa interior layered deposits (ILD) and is being concentrated as a lag deposit adjacent to the lower layers of Candor Mensa and at the base in the form of dark aeolian material. Due to the similar geologic context associated with hematite-bearing and ILD materials throughout the Valles Marineris canyon system, the insight gained from studying these materials surrounding Candor Mensa can likely be applicable to similar layered deposits throughout Valles Marineris.

Published
2014
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20. Volcanic glass signatures in spectroscopic survey of newly proposed lunar pyroclastic deposits

Author

Jessica M. Sunshine, Sebastien Besse, and Lisa R. Gaddis

Subjects
geography, geography.geographical_feature_category, Geochemistry, Pyroclastic rock, Mineralogy, Volcanism, Mantle (geology), Volcanic glass, Geophysics, Volcano, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Geology
Abstract

Moon Mineralogy Mapper spectroscopic observations are used to assess the mineralogy of five sites that have recently been proposed to include lunar dark mantle deposits (DMDs). Volcanic glasses have, for the first time, clearly been identified at the location of three of the proposed pyroclastic deposits. This is the first time that volcanic glasses have been identified at such a small scale on the lunar surface from remote sensing observations. Deposits at Birt E, Schluter, and Walther A appear to be glassy DMDs. Deposits at Birt E and Schluter show (1) morphological evidence suggesting a likely vent and (2) mineralogical evidence indicative of the presence of volcanic glasses. The Walther A deposits, although they show no morphological evidence of vents, have the spectroscopic characteristics diagnostic of volcanic glasses. The deposits of the Freundlich-Sharonov basin are separated in two areas: (1) the Buys-Ballot deposits lack mineralogical and morphological evidence and thus are found to be associated with mare volcanism not with DMDs and (2) the Anderson crater deposits, which do not exhibit glassy DMD signatures, but they appear to be associated with possible vent structures and so may be classifiable as DMDs. Finally, dark deposits near the crater Kopff are found to be associated with likely mare volcanism and not associated with DMDs. The spectral identification of volcanic glass seen in many of the potential DMDs is a strong indicator of their pyroclastic origin.

Published
2014
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22. Development of the Moon

Author

Harrison H. Schmitt, Michael B. Duke, Lisa R. Gaddis, and G. Jeffrey Taylor

Subjects
Solar System, Interpretation (philosophy), Earth science, Crust, Context (language use), Natural resource, Space exploration, Physics::Geophysics, Astrobiology, Geochemistry and Petrology, Physics::Space Physics, Gravity well, Natural satellite, Astrophysics::Earth and Planetary Astrophysics, Geology
Abstract

This book focuses largely on new results from recent missions and on their implications for how we interpret results from older missions. The new results have also renewed awareness of the Moon as a future target for exploration and many people see development of the Moon, particularly its resources, as a key step in the future exploration of the solar system (Aldridge et al. 2004). The interpretation of the lunar data sets in the context of future exploration and development of the Moon is, therefore, parallel to new scientific interpretations. This is in a sense a forward-looking view inspired in part by New Views of the Moon perspectives. It is also timely, as the United States is currently reconsidering its space exploration program, with a greater focus on renewed exploration of the Moon. Earth’s Moon can be looked upon as an enormous Earth-orbiting Space Station, a natural satellite outside of Earth’s gravity well, with raw materials that can be put to practical use as humanity expands outward into the Universe. As outlined in previous chapters, new remote-sensing data for the Moon have reinvigorated lunar science and improved understanding of the Moon’s composition, the ages of its prominent formative events, and the character of the earliest lunar crust and its subsequent geologic evolution. In this chapter, we consider how we might use lunar materials for exploration, utilization, and development of the Moon. The Moon offers a nearby location from which to develop resources and capabilities to explore further in the Solar System. The natural resources of the Moon include minerals, rocks, and soils, which can be processed to produce metals, oxygen, glass, ceramics, and other useful products (McKay et al. 1992). Water ice may exist near the poles and low concentrations of volatiles deposited by solar wind (H, He, C, N) …

Published
2006
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23. Compositional analyses of lunar pyroclastic deposits

Author

M. Staid, B. Ray Hawke, Noah E. Petro, James A. Tyburczy, and Lisa R. Gaddis

Subjects
Basalt, geography, geography.geographical_feature_category, Olivine, Lunar mare, Geochemistry, Pyroclastic rock, Astronomy and Astrophysics, Bead, engineering.material, Volcanic glass, Volcano, Space and Planetary Science, visual_art, visual_art.visual_art_medium, engineering, Mafic, Geology
Abstract

The 5-band Clementine UVVIS data at ∼100 m/pixel were used to examine the compositions of 75 large and small lunar pyroclastic deposits (LPDs), and these were compared to representative lunar maria and highlands deposits. Results show that the albedo, spectral color, and inferred composition of most LPDs are similar to those of low-titanium, mature lunar maria. These LPDs may have consisted largely of fragmented basalt, with substantial components of iron-bearing mafic minerals (pyroxenes, olivine) and smaller amounts (if any) of volcanic glass. Several smaller LPDs also show substantial highland components. Three classes of very large deposits can be distinguished from most LPDs and from each other on the basis of crystallinity and possible titanium content of their pyroclastic components. One class has spectral properties that are dominated by high-titanium, crystallized “black beads” (e.g., Taurus–Littrow), a second consists of a mixture of high-titanium glasses and beads with a higher glass/bead ratio (Sulpicius Gallus) than that of Taurus–Littrow, and a third has a significant component of quenched iron-bearing volcanic glasses (Aristarchus) with possible moderate titanium contents. Although areally extensive, these three classes of very large pyroclastic deposits compose only 20 of the 75 deposits studied (∼27%), and eruption of such materials was thus likely to have been less frequent on the Moon.

Published
2003
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25. Editorial Introduction: Lunar Reconnaissance Orbiter, part II

Author

Lisa R. Gaddis, Noah E. Petro, and John W. Keller

Subjects
Spacecraft, Data products, business.industry, Geodetic datum, Narrow angle, High resolution, Astronomy and Astrophysics, Astrobiology, law.invention, Orbiter, Space and Planetary Science, law, business, Geology, Space environment, Remote sensing
Abstract

The Lunar Reconnaissance Orbiter (LRO) mission has shifted our understanding of the history of the Moon. The seven instruments on LRO each have contributed to creating new paradigms for the evolution of the Moon by providing unprecedented measurements of the surface, subsurface, and lunar environment. In this second volume of the LRO Special Issue, we present 21 papers from a broad range of the areas of investigation from LRO, from the volatile inventory, to the shape of the Moon's surface, to its rich volcanic history, and the interactions between the lunar surface and the space environment. These themes provide rich science for the instrument teams, as well as for the broader science com- munity who continue to use the LRO data in their research. Each paper uses publicly available data from one or more instruments on LRO, illustrating the value of a robust spacecraft. For example, the production of high-resolution topographic data products from the LRO Camera Narrow Angle Camera (Henriksen et al., pp. 122-137, this issue) rely on the accurate geodetic grid produced by the LOLA instrument (Mao et al., pp. 55-69, this issue; Smith et al., pp. 70-91, this issue). Additionally, analysis of LRO data coupled with other spacecraft data, such as LADEE (Hurley et al., pp. 31-37, this issue) and GRAIL (e.g., Jozwiak et al., pp. 224-231, this issue) illustrate the utility of merging not only data from multiple instruments, but also multiple orbital platforms. These synergistic studies show the value of the inter-team approach adopted by the LRO mission. This second volume represents the culmination of an extensive effort to highlight the high-quality science still being produced by the LRO instrument teams, even after more than seven years in orbit at the Moon.

Published
2017
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26. Rock types of South Pole-Aitken basin and extent of basaltic volcanism

Author

Carle M. Pieters, Michael B. Duke, Bradley L. Jolliff, Lisa R. Gaddis, and James W. Head

Subjects
Basalt, Atmospheric Science, Ecology, Gabbro, Geochemistry, Paleontology, Soil Science, Forestry, Crust, Aquatic Science, South Pole–Aitken basin, Oceanography, Anorthosite, Igneous rock, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mafic, Norite, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

The enormous pre-Nectarian South Pole-Aitken (SPA) basin represents a geophysically and compositionally unique region on the Moon. We present and analyze the mineralogical diversity across this basin and discuss the implications for basin evolution. Rock types are derived from Clementine multispectral data based on diagnostic characteristics of ferrous absorptions in fresh materials. Individual areas are characterized as noritic (dominated by low-Ca pyroxene), gabbroic/basaltic (dominated by high-Ca pyroxene), feldspathic (

Published
2001
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27. Compositional analyses of small lunar pyroclastic deposits using Clementine multispectral data

Author

Mark S. Robinson, Lisa R. Gaddis, Cassandra R. Coombs, and B. Ray Hawke

Subjects
Atmospheric Science, Lunar mare, Geochemistry, Soil Science, Pyroclastic rock, Mineralogy, Aquatic Science, Oceanography, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, Basalt, geography, Explosive eruption, geography.geographical_feature_category, Ecology, Paleontology, Forestry, Volcanic rock, Igneous rock, Geophysics, Geology of the Moon, Space and Planetary Science, Mafic, Geology
Abstract

Clementine ultraviolet-visible (UVVIS) data are used to examine the compositions of 18 pyroclastic deposits (15 small, three large) at 13 sites on the Moon. Compositional variations among pyroclastic deposits largely result from differing amounts of new basaltic (or juvenile) material and reworked local material entrained in their ejecta upon eruption. Characterization of pyroclastic deposit compositions allows us to understand the mechanisms of lunar explosive volcanism. Evidence for compositional differences between small pyroclastic deposits at a single site is observed at Atlas crater. At all sites, compositional variation among the small pyroclastic deposits is consistent with earlier classification based on Earth-based spectra: three compositional groups can be observed, and the trend of increasing mafic absorption band strength from Group 1 to Group 2 to Group 3 is noted. As redefined here, Group 1 deposits include those of Alphonsus West, Alphonsus Southeast, Alphonsus Northeast 2, Atlas South, Cruger, Franklin, Grimaldi, Lavoisier, Oppenheimer, Orientale, and Riccioli. Group 1 deposits resemble lunar highlands, with weak mafic bands and relatively high UV/VIS ratios. Group 2 deposits include those of Alphonsus Northeast 1, Atlas North, Eastern Frigoris East and West, and Aristarchus Plateau; Group 2 deposits are similar to mature lunar maria, with moderate mafic band depths and intermediate UV/VIS ratios. The single Group 3 deposit, J. Herschel, has a relatively strong mafic band and a low UV/VIS ratio, and olivine is a likely juvenile component. Two of the deposits in these groups, Orientale and Aristarchus, are large pyroclastic deposits. The third large pyroclastic deposit, Apollo 17/Taurus Littrow, has a very weak mafic band and a high UV/VIS ratio and it does not belong to any of the compositional groups for small pyroclastic deposits. The observed compositional variations indicate that highland and mare materials are also present in many large and small pyroclastic deposits, and they suggest that volcanic glasses or spheres may not be dominant juvenile components in all large pyroclastic deposits.

Published
2000
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28. Preliminary results on photometric properties of materials at the Sagan Memorial Station, Mars

Author

Daniel T. Britt, Lisa R. Gaddis, James F. Bell, Nicolas Thomas, Frank Trauthan, Robert S. Anderson, Jeffrey R. Johnson, Pete Smith, Justin N. Maki, Mark T. Lemmon, Gabriele Arnold, Ralf Jaumann, Laurence A. Soderblom, Robert J. Reid, Kenneth E. Herkenhoff, Randolph L. Kirk, Scott L. Murchie, Nathan T. Bridges, and Andreas Dummel

Subjects
Atmospheric Science, Forward scatter, Equator, Soil Science, Mineralogy, STRIPS, Aquatic Science, Oceanography, law.invention, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, Remote sensing, Ecology, Scattering, Phase angle, Paleontology, Forestry, Mars Exploration Program, Hapke parameters, Geophysics, Space and Planetary Science, Material properties, Geology
Abstract

Reflectance measurements of selected rocks and soils over a wide range of illumination geometries obtained by the Imager for Mars Pathfinder (IMP) camera provide constraints on interpretations of the physical and mineralogical nature of geologic materials at the landing site. The data sets consist of (1) three small “photometric spot” subframed scenes, covering phase angles from 20° to 150°; (2) two image strips composed of three subframed images each, located along the antisunrise and antisunset lines (photometric equator), covering phase angles from ∼0° to 155°; and (3) full-image scenes of the rock “Yogi,” covering phase angles from 48° to 100°. Phase functions extracted from calibrated data exhibit a dominantly backscattering photometric function, consistent with the results from the Viking lander cameras. However, forward scattering behavior does appear at phase angles >140°, particularly for the darker gray rock surfaces. Preliminary efforts using a Hapke scattering model are useful in comparing surface properties of different rock and soil types but are not well constrained, possibly due to the incomplete phase angle availability, uncertainties related to the photometric function of the calibration targets, and/or the competing effects of diffuse and direct lighting. Preliminary interpretations of the derived Hapke parameters suggest that (1) red rocks can be modeled as a mixture of gray rocks with a coating of bright and dark soil or dust, and (2) gray rocks have macroscopically smoother surfaces composed of microscopically homogeneous, clear materials with little internal scattering, which may imply a glass-like or varnished surface.

Published
1999
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29. General geology and geomorphology of the Mars Pathfinder landing site

Author

Ronald Greeley, Lisa R. Gaddis, Randolph L. Kirk, Ruslan O. Kuzmin, Matthew P. Golombek, A. W. Ward, Laurence A. Soderblom, T. J. Parker, and Kenneth L. Tanaka

Subjects
Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Landform, Ventifact, Amazonian, Paleontology, Soil Science, Fluvial, Forestry, Mars Exploration Program, Aquatic Science, Oceanography, Chryse Planitia, Sedimentary depositional environment, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Hesperian, Geomorphology, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

The Mars Pathfinder (MPF) spacecraft landed on relatively young (late Hesperian-early Amazonian; 3.1–0.7 Ga) plains in Chryse Planitia near the mouth of Ares Vallis. Images returned from the spacecraft reveal a complex landscape of ridges and troughs, large hills and crater rims, rocks and boulders of various sizes and shapes, and surficial deposits, indicating a complex, multistage geologic history of the landing site. After the deposition of one or more bedrock units, depositional and erosional fluvial processes shaped much of the present landscape. Multiple erosional events are inferred on the basis of observations of numerous channels, different orientations of many streamlined tails from their associated knobs and hills, and superposition of lineations and streamlines. Medium- and small-scale features, interpreted to be related to late-stage drainage of floodwaters, are recognized in several areas at the landing site. Streamlined knobs and hills seen in Viking orbiter images support this inference, as they seem to be complex forms, partly erosional and partly depositional, and may also indicate a series of scouring and depositional events that, in some cases, further eroded or partially buried these landforms. Although features such as these are cited as evidence for catastrophic flooding at Ares Vallis, some of these features may also be ascribed to alternative primary or secondary depositional processes, such as glacial or mass-wasting processes. Close inspection of the landing site reveals rocks that are interpreted to be volcanic in origin and others that may be conglomeratic. If such sedimentary rocks are confirmed, fluvial processes have had a greater significance on Mars than previously thought. For the last several hundred million to few billion years, eolian processes have been dominant. Dunes and dune-like features, ventifacts, and deflation and exhumation features around several rocks probably are the most recent landforms. The relatively pristine nature of the overall landscape at the MPF site suggests weathering and erosion processes on Mars are exceptionally slow.

Published
1999
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30. Digital photogrammetric analysis of the IMP camera images: Mapping the Mars Pathfinder landing site in three dimensions

Author

Pete Smith, Kris J. Becker, A. W. Ward, K. Thompson, Bonnie L. Redding, D. Cook, Daniel T. Britt, Lisa R. Gaddis, Trent M. Hare, Elpitha Howington-Kraus, Laurence A. Soderblom, Egon Dorrer, E. Lee, Jeffrey R. Johnson, Randolph L. Kirk, Donna M. Galuszka, and J. Blue

Subjects
Atmospheric Science, Ecology, Spectrometer, Computer science, business.industry, Paleontology, Soil Science, Forestry, Terrain, Ranging, Mars Exploration Program, Aquatic Science, Oceanography, Identification (information), Geophysics, Photogrammetry, Software, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), business, Parallax, Earth-Surface Processes, Water Science and Technology, Remote sensing
Abstract

This paper describes our photogrammetric analysis of the Imager for Mars Pathfinder data, part of a broader program of mapping the Mars Pathfinder landing site in support of geoscience investigations. This analysis, carried out primarily with a commercial digital photogrammetric system, supported by our in-house Integrated Software for Imagers and Spectrometers (ISIS), consists of three steps: (1) geometric control: simultaneous solution for refined estimates of camera positions and pointing plus three-dimensional (3-D) coordinates of ∼10 3 features sitewide, based on the measured image coordinates of those features; (2) topographic modeling: identification of ∼3 x 10 5 closely spaced points in the images and calculation (based on camera parameters from step 1) of their 3-D coordinates, yielding digital terrain models (DTMs); and (3) geometric manipulation of the data: combination of the DTMs from different stereo pairs into a sitewide model, and reprojection of image data to remove parallax between the different spectral filters in the two cameras and to provide an undistorted planimetric view of the site. These processes are described in detail and example products are shown. Plans for combining the photogrammetrically derived topographic data with spectrophotometry are also described. These include photometric modeling using surface orientations from the DTM to study surface microtextures and improve the accuracy of spectral measurements, and photoclinometry to refine the DTM to single-pixel resolution where photometric properties are sufficiently uniform. Finally, the inclusion of rover images in a joint photogrammetric analysis with IMP images is described. This challenging task will provide coverage of areas hidden to the IMP, but accurate ranging of distant features can be achieved only if the lander is also visible in the rover image used.

Published
1999
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32. Results from the Mars Pathfinder Camera

Author

Mark T. Lemmon, R. M. Sablotny, James F. Bell, E. Wegryn, T. J. Parker, Jeffrey R. Johnson, Peter H. Smith, Michael C. Malin, Scott L. Murchie, R. L. Kirk, Martin G. Tomasko, Carol R. Stoker, Ralf Jaumann, H. U. Keller, L. A. Soderblom, Ryan C. Sullivan, N. Thomas, Justin N. Maki, R. J. Reid, W. Ward, Kenneth E. Herkenhoff, Juergen Oberst, Daniel T. Britt, Ronald Greeley, Lisa R. Gaddis, and Nathan T. Bridges

Subjects
Minerals, Multidisciplinary, Haze, Spectral signature, Extraterrestrial Environment, Atmosphere, Ice, Mars, Water, Mineralogy, Wind, Mars Exploration Program, Impactite, Martian surface, Aeolian processes, Geology, Water vapor
Abstract

Images of the martian surface returned by the Imager for Mars Pathfinder (IMP) show a complex surface of ridges and troughs covered by rocks that have been transported and modified by fluvial, aeolian, and impact processes. Analysis of the spectral signatures in the scene (at 440- to 1000-nanometer wavelength) reveal three types of rock and four classes of soil. Upward-looking IMP images of the predawn sky show thin, bluish clouds that probably represent water ice forming on local atmospheric haze (opacity ∼0.5). Haze particles are about 1 micrometer in radius and the water vapor column abundance is about 10 precipitable micrometers.

Published
1997
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33. The imager for Mars Pathfinder experiment

Author

Haraldur P. Gunnlaugsson, N. Thomas, Martin G. Tomasko, Laurence A. Soderblom, Fritz Gliem, H. U. Keller, Jens Martin Knudsen, Stubbe Hviid, Peter H. Smith, Robert Sullivan, Devon G. Crowe, Walter Goetz, Daniel T. Britt, Ronald Greeley, Lisa R. Gaddis, P. Rueffer, Morten Madsen, R. J. Reid, and Randolph L. Kirk

Subjects
Atmospheric Science, Opacity, Multispectral image, Soil Science, Field of view, Aquatic Science, Oceanography, Optics, Geochemistry and Petrology, Shutter, Earth and Planetary Sciences (miscellaneous), Calibration, Depth of field, Earth-Surface Processes, Water Science and Technology, Remote sensing, Ecology, Pixel, business.industry, Paleontology, Forestry, Mars Exploration Program, Geophysics, Space and Planetary Science, business, Geology
Abstract

The imager for Mars Pathfinder (IMP), a stereoscopic, multispectral camera, is described in terms of its capabilities for studying the Martian environment. The camera's two eyes, separated by 15.0 cm, provide the camera with range-finding ability. Each eye illuminates half of a single CCD detector with a field of view of 14.4×14.0° and has 12 selectable filters. The ƒ/18 optics have a large depth of field, and no focussing mechanism is required; a mechanical shutter is avoided by using the frame transfer capability of the 512×512 CCD. The resolving power of the camera, 0.98 mrad/pixel, is approximately the same as the Viking Lander cameras; however, the signal-to-noise ratio for IMP greatly exceeds Viking, approaching 350. This feature along with the stable calibration of the filters between 440 and 1000 nm distinguishes IMP from Viking. Specially designed targets are positioned on the Lander; they provide information on the magnetic properties of wind-blown dust, measure the wind vectors, and provide radiometric standard reflectors for calibration. Also, eight low-transmission filters are included for imaging the Sun directly at multiple wavelengths, giving IMP the ability to measure dust opacity and potentially the water vapor content. Several experiments beyond the requisite color panorama are described in detail: contour mapping of the local terrain, multispectral imaging of the surrounding rock and soil to study local mineralogy, viewing of three wind socks, measuring atmospheric opacity and water vapor content, and estimating the magnetic properties of wind-blown dust. This paper is intended to serve as a guide to understanding the scientific integrity of the IMP data that will be returned from Mars starting on July 4, 1997.

Published
1997
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34. Modeling of fluidized ejecta emplacement over digital topography on Venus

Author

Jeffrey R. Johnson and Lisa R. Gaddis

Subjects
Atmospheric Science, Soil Science, Venus, Aquatic Science, Oceanography, Gravitational acceleration, Physics::Fluid Dynamics, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Ejecta, Earth-Surface Processes, Water Science and Technology, Ecology, biology, Turbulence, Paleontology, Forestry, Laminar flow, Geophysics, Mechanics, biology.organism_classification, Flow (mathematics), Space and Planetary Science, Outflow, Astrophysics::Earth and Planetary Astrophysics, Energy source, Geology
Abstract

The FLOW computer model of McEwen and Malin (1989) modified for application to the study of Venus fluidized ejecta blankets (FEBs) demonstrates that relatively low viscosities, yield strengths, and initial velocities are required to duplicate the observed flow paths of the outflow materials. The model calculates the velocities and simulated flow paths of gravity flows over Magellan topography. The model is formulated to determine flow movements from initial conditions, gravitational acceleration, and resistance to motion as described by Coulomb, viscous, and turbulent resistance forces. Successful duplication of observed FEB flow paths has been achieved for the FEB craters Addams, Isabella, and Cochran. When used as a simple energy-line model, the model requires low coefficients of friction to extend FEBs to near their observed termini in the synthetic aperture radar (SAR) imagery, although the resulting straight flow lines do not follow the observed flow paths well. For Bingham flow, the model requires low values of viscosity and yield strength which are more similar to pyroclastic or debris flows than basaltic lavas. Flows of 100-m depth require 1 to 2 orders of magnitude higher values of both viscosity and yield strength than 10-m-deep flows. The complicated nature of the flow lines for the low velocity model suggests that FEBs were probably emplaced under variably laminar and turbulent flow conditions, where underlying topography influenced both the direction and energy of flow materials.

Published
1996
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35. Textures of the Soils and Rocks at Gusev Crater from Spirit's Microscopic Imager

Author

J. W. Rice, S. W. Squyres, Alexander G. Hayes, N. A. Cabrol, D. S. Bass, N. Spanovich, Stubbe F. Hviid, Alian Wang, Kjartan M. Kinch, Kenneth E. Herkenhoff, James F. Bell, Jeffrey R. Johnson, Morten Madsen, M. Sims, Lisa R. Gaddis, L. A. Soderblom, Harry Y. McSween, P. Bertelsen, Ryan C. Sullivan, Raymond E. Arvidson, Peter H. Smith, Scott M. McLennan, and Justin N. Maki

Subjects
Geologic Sediments, geography, Multidisciplinary, geography.geographical_feature_category, Extraterrestrial Environment, Mars, Water, Mineralogy, Weathering, Volcanic Eruptions, Wind, Igneous textures, Impactite, Mars Exploration Program, Volcanic rock, Igneous rock, Volcano, Impact crater, Geology
Abstract

The Microscopic Imager on the Spirit rover analyzed the textures of the soil and rocks at Gusev crater on Mars at a resolution of 100 micrometers. Weakly bound agglomerates of dust are present in the soil near the Columbia Memorial Station. Some of the brushed or abraded rock surfaces show igneous textures and evidence for alteration rinds, coatings, and veins consistent with secondary mineralization. The rock textures are consistent with a volcanic origin and subsequent alteration and/or weathering by impact events, wind, and possibly water.

Published
2004
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36. Characterization of previously unidentified lunar pyroclastic deposits using Lunar Reconnaissance Orbiter Camera data

Author

Lisa R. Gaddis, J. Olaf Gustafson, Thomas A. Giguere, B. R. Hawke, and James F. Bell

Subjects
Atmospheric Science, Ecology, Geochemistry, Paleontology, Soil Science, Pyroclastic rock, Mineralogy, Narrow angle, Forestry, Aquatic Science, Oceanography, law.invention, Orbiter, Geophysics, Impact crater, Space and Planetary Science, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Geology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] We used a Lunar Reconnaissance Orbiter Camera (LROC) global monochrome Wide-angle Camera (WAC) mosaic to conduct a survey of the Moon to search for previously unidentified pyroclastic deposits. Promising locations were examined in detail using LROC multispectral WAC mosaics, high-resolution LROC Narrow Angle Camera (NAC) images, and Clementine multispectral (ultraviolet-visible or UVVIS) data. Out of 47 potential deposits chosen for closer examination, 12 were selected as probable newly identified pyroclastic deposits. Potential pyroclastic deposits were generally found in settings similar to previously identified deposits, including areas within or near mare deposits adjacent to highlands, within floor-fractured craters, and along fissures in mare deposits. However, a significant new finding is the discovery of localized pyroclastic deposits within floor-fractured craters Anderson E and F on the lunar farside, isolated from other known similar deposits. Our search confirms that most major regional and localized low-albedo pyroclastic deposits have been identified on the Moon down to ∼100 m/pix resolution, and that additional newly identified deposits are likely to be either isolated small deposits or additional portions of discontinuous, patchy deposits.

Published
2012
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37. New insight into lunar impact melt mobility from the LRO camera

Author

Thomas A. Giguere, Simon A. Kattenhorn, W. B. Garry, C. M. Caudill, Veronica J. Bray, C. H. van der Bogert, Lajos Keszthelyi, Livio L. Tornabene, Bashar Rizk, B. R. Hawke, Alfred S. McEwen, and Lisa R. Gaddis

Subjects
Orbiter, Geophysics, Lunar craters, Impact crater, law, Lava, Melt pond, General Earth and Planetary Sciences, Extended time, Geology, Cooling time, law.invention
Abstract

[1] The Lunar Reconnaissance Orbiter Camera (LROC) is systematically imaging impact melt deposits in and around lunar craters at meter and sub-meter scales. These images reveal that lunar impact melts, although morphologically similar to terrestrial lava flows of similar size, exhibit distinctive features (e.g., erosional channels). Although generated in a single rapid event, the post-impact mobility and morphology of lunar impact melts is surprisingly complex. We present evidence for multi-stage influx of impact melt into flow lobes and crater floor ponds. Our volume and cooling time estimates for the post-emplacement melt movements noted in LROC images suggest that new flows can emerge from melt ponds an extended time period after the impact event.

Published
2010
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38. Lava-flow characterization at Pisgah volcanic field, California, with multiparameter imaging radar

Author

Lisa R. Gaddis

Subjects
Synthetic aperture radar, geography, geography.geographical_feature_category, Lava, Alluvial fan, Geology, law.invention, Wavelength, Volcano, law, Radar imaging, Sedimentary rock, Radar, Geomorphology, Remote sensing
Abstract

Multi-incidence-angle (in the 25° to 55° range) radar data acquired by the NASA/JPL Airborne Synthetic Aperture Radar (AIRSAR) at three wavelengths simultaneously and displayed at three polarizations are examined for their utility in characterizing lava flows at Pisgah volcanic field, California. Pisgah lava flows were erupted in three phases; flow textures consist of hummocky pahoehoe, smooth pahoehoe, and aa (with and without thin sedimentary cover). Of the eight AIRSAR images used here, four were calibrated to within an accuracy of ±2 dB with trihedral corner reflectors, and data from these calibrations were used to process the additional images to a conservatively estimated ±5 dB level of accuracy. Calibrated radar backscatter data (σ°, in dB) were plotted as a function of incidence angle at three wavelengths (P-band, 68 cm; L-band, 24 cm; and C-band, 5.6 cm) and three polarizations (HH, horizontal transmit/horizontal receive; HV, horizontal transmit/vertical receive; and VV, vertical transmit/vertical receive) for eight major units at Pisgah for which multi-incidence-angle AIRSAR data were available. The eight units consist of near-vent and distal aa flows; near-vent and distal, hummocky pahoehoe flows; a mantled, hummocky pahoehoe flow; a platform pahoehoe flow; an alluvial fan; and a playa. Analyses of these backscatter data show that major unmodified volcanic units at Pisgah are readily distinguishable from each other and that they exhibit diffuse (HH, VV) and/or multiple (HV) scattering behavior typical of rough surfaces at these wavelengths. These analyses show that discrimination of smooth lavas (platform pahoehoe) from mantled units with greater primary roughness (hummocky pahoehoe) is difficult and must rely on supporting observations (such as evidence of localized weathering and/or sediment deposition, contrast with surrounding units, and superposition of flow units). L-band backscatter and image data at HV polarization show the best discrimination of Pisgah lava flows, with optimal unit separation observed between ∼40° and 50° incidence angles. Backscatter data shown as a function of relative age of Pisgah flows indicate that dating of lava flows on the basis of average radar backscatter may yield ambiguous results if primary flow textures and modification processes are not well understood.

Published
1992
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39. Thorium abundances on the Aristarchus plateau: Insights into the composition of the Aristarchus pyroclastic glass deposits

Author

David J. Lawrence, B. R. Hawke, Justin J. Hagerty, and Lisa R. Gaddis

Subjects
Atmospheric Science, Soil Science, chemistry.chemical_element, Mineralogy, Pyroclastic rock, Aquatic Science, Oceanography, Impact crater, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Ejecta, Earth-Surface Processes, Water Science and Technology, geography, Plateau, geography.geographical_feature_category, Ecology, Paleontology, Thorium, Forestry, Volcanic rock, Igneous rock, Geophysics, chemistry, Volcano, Space and Planetary Science, Geology
Abstract

[1] Thorium (Th) data from the Lunar Prospector gamma ray spectrometer (LP-GRS) are used to constrain the composition of lunar pyroclastic glass deposits on top of the Aristarchus plateau. Our goal is to use forward modeling of LP-GRS Th data to measure the Th abundances on the plateau and then to determine if the elevated Th abundances on the plateau are associated with the pyroclastic deposits or with thorium-rich ejecta from Aristarchus crater. We use a variety of remote sensing data to show that there is a large, homogenous portion of the pyroclastics on the plateau that has seen little or no contamination from the Th-rich ejecta of Aristarchus crater. Our results show that the uncontaminated pyroclastic glasses on Aristarchus plateau have an average Th content of 6.7 ppm and ∼7 wt % TiO2. These Th and Ti values are consistent with Th-rich, intermediate-Ti yellow glasses from the lunar sample suite. On the basis of this information, we use petrologic equations and interelement correlations for the Moon to estimate the composition of the source region from which the Aristarchus glasses were derived. We find that the source region for the Aristarchus glasses contained high abundances of heat-producing elements, which most likely served as a thermal driver for the prolonged volcanic activity in this region of the Moon.

Published
2009
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40. Surface processes recorded by rocks and soils on Meridiani Planum, Mars: Microscopic Imager observations during Opportunity's first three extended missions

Author

Timothy J. Parker, James F. Bell, Craig E. Leff, Lisa R. Gaddis, Randolph L. Kirk, Scott M. McLennan, Justin N. Maki, Kevin F. Mullins, Raymond E. Arvidson, Trent M. Hare, Elpitha Howington-Kraus, Mary G. Chapman, N. Spanovich, Catherine M. Weitz, E. Lee, A. Yingst, M. Sims, Peter Lanagan, Kris J. Becker, Daniel A. Stolper, John P. Grotzinger, Kenneth E. Herkenhoff, Charles Budney, Janet M. Barrett, Paul E. Geissler, Bonnie L. Redding, Robert Sullivan, Steven W. Squyres, Laurence A. Soderblom, Mark R. Rosiek, Patricia A. Garcia, Brenda J. Franklin, J. Torson, T. Sucharski, Robert S. Anderson, D. Cook, Bethany L. Ehlmann, Brent A. Archinal, Richard Springer, Andrew H. Knoll, Laszlo P. Keszthelyi, Donna M. Galuszka, Robert M. Sucharski, and Jeffrey R. Johnson

Subjects
Meridiani Planum, Atmospheric Science, Outcrop, Soil Science, Aquatic Science, Oceanography, Sedimentary structures, Sedimentary depositional environment, Petrography, Paleontology, Impact crater, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Geomorphology, Earth-Surface Processes, Water Science and Technology, Ecology, biology, Forestry, Mars Exploration Program, Erebus, biology.organism_classification, Geophysics, Space and Planetary Science, Geology
Abstract

The Microscopic Imager (MI) on the Mars Exploration Rover Opportunity has returned images of Mars with higher resolution than any previous camera system, allowing detailed petrographic and sedimentological studies of the rocks and soils at the Meridiani Planum landing site. Designed to simulate a geologist's hand lens, the MI is mounted on Opportunity's instrument arm and can resolve objects 0.1 mm across or larger. This paper provides an overview of MI operations, data calibration, and analysis of MI data returned during the first 900 sols (Mars days) of the Opportunity landed mission. Analyses of Opportunity MI data have helped to resolve major questions about the origin of observed textures and features. These studies support eolian sediment transport, rather than impact surge processes, as the dominant depositional mechanism for Burns formation strata. MI stereo observations of a rock outcrop near the rim of Erebus Crater support the previous interpretation of similar sedimentary structures in Eagle Crater as being formed by surficial flow of liquid water. Well-sorted spherules dominate ripple surfaces on the Meridiani plains, and the size of spherules between ripples decreases by about 1 mm from north to south along Opportunity's traverse between Endurance and Erebus craters.

Published
2008
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42. Overview of the Microscopic Imager Investigation during Spirit's first 450 sols in Gusev crater

Author

Mark R. Rosiek, Brenda J. Franklin, Richard Springer, Kevin F. Mullins, Kris J. Becker, Brent A. Archinal, Albert S. Yen, Charles Budney, Robert M. Sucharski, James F. Bell, Nathalie A. Cabrol, Craig E. Leff, T. Sucharski, Sarah Stewart Johnson, Donna M. Galuszka, Robert S. Anderson, Janet M. Barrett, K. E. Herkenhoff, Ella Mae Lee, Morten Madsen, Patricia A. Garcia, S. W. Squyres, Mark T. Lemmon, Bonnie L. Redding, D. Cook, N. Spanovich, Jack D. Farmer, Kjartan M. Kinch, Lisa R. Gaddis, B. L. Ehlmann, Mary G. Chapman, M. Sims, Trent M. Hare, Elpitha Howington-Kraus, Raymond E. Arvidson, Randolph L. Kirk, J. Torson, Lutz Richter, Laurence A. Soderblom, R. J. Sullivan, Justin N. Maki, and Jeffrey R. Johnson

Subjects
Atmospheric Science, Ecology, Paleontology, Soil Science, Pyroclastic rock, Mineralogy, Forestry, Crust, Mars Exploration Program, Igneous textures, Aquatic Science, Oceanography, Petrography, Geophysics, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Aeolian processes, Radiometric dating, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

The Microscopic Imager (MI) on the Mars Exploration Rover Spirit has returned images of Mars with higher resolution than any previous camera system, allowing detailed petrographic and sedimentological studies of the rocks and soils at the Gusev landing site. Designed to simulate a geologist's hand lens, the MI is mounted on Spirit's instrument arm and can resolve objects 0.1 mm in size or larger. This paper provides an overview of MI operations, data calibration, processing, and analysis of MI data returned during the first 450 sols (Mars days) of the Spirit landed mission. The primary goal of this paper is to facilitate further analyses of MI data by summarizing the methods used to acquire and process the data, the radiometric and geometric accuracy of MI data products, and the availability of archival products. In addition, scientific results of the MI investigation are summarized. MI observations show that poorly sorted soils are common in Gusev crater, although aeolian bedforms have well-sorted coarse sand grains on their surfaces. Abraded surfaces of plains rocks show igneous textures, light-toned veins or fracture-filling minerals, and discrete coatings. The rocks in the Columbia Hills have a wide variety of granular textures, consistent with volcaniclastic or impact origins. Case hardening and submillimeter veins observed in the rocks as well as soil crusts and cemented clods imply episodic subsurface aqueous fluid movement, which has altered multiple geologic units in the Columbia Hills. The MI also monitored Spirit's solar panels and the magnets on the rover's deck.

Published
2006
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43. Remote sensing studies of the Dionysius region of the Moon

Author

G.A. Smith, B. Ray Hawke, J. J. Gillis-Davis, Paul G. Lucey, Lisa R. Gaddis, Paul D. Spudis, David T. Blewett, G. J. Taylor, and Thomas A. Giguere

Subjects
Basalt, Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Paleontology, Soil Science, Mineralogy, Forestry, Aquatic Science, Albedo, Oceanography, Spectral line, Ray system, Volcanic rock, Geophysics, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Mafic, Ejecta, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] The Dionysius region is located near the western edge of Mare Tranquillitatis and is centered on Dionysius crater, which exhibits a well-developed dark ray system. Proposed origins for these dark rays included impact melt deposits and dark primary ejecta. The region also contains extensive deposits of Cayley-type light plains. Clementine multispectral images and a variety of spacecraft photography were utilized to investigate the composition and origin of geologic units in the Dionysius region. The portions of the dark rays for which spectral and chemical data were obtained are composed of mare debris contaminated with minor amounts of highland material. Both five-point spectra and values of the optical maturity (OMAT) parameter indicate that the dark rays are dominated by mare basalts, not glassy impact melts. The high-albedo rays associated with Dionysius exhibit FeO and TiO2 values that are lower than those of the adjacent dark ray surfaces and OMAT values that indicate that bright ray surfaces are not fully mature. The high-albedo rays are bright largely because of the contrast in albedo between ray material containing highlands-rich ejecta and the adjacent mare-rich surfaces. The mafic debris ejected by Dionysius was derived from a dark, iron-rich unit exposed high on the inner wall of the crater. This layer probably represents a mare deposit that was present at the surface of the preimpact target site. With one possible exception, there is no evidence for buried mare basalts associated with Cayley plains in the region.

Published
2006
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44. Pitted cones and domes on Mars: Observations in Acidalia Planitia and Cydonia Mensae using MOC, THEMIS, and TES data

Author

Lisa R. Gaddis, Laszlo P. Keszthelyi, and William H. Farrand

Subjects
Basalt, Atmospheric Science, Ecology, Evaporite, Paleontology, Soil Science, Forestry, Mars Exploration Program, Aquatic Science, Oceanography, Dome (geology), Geophysics, Domo, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Sedimentary rock, Layering, Geomorphology, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Domes and cones with summit pits located in Acidalia Planitia and Cydonia Mensae were studied using MOC and THEMIS images and a TES-derived thermal inertia map. North of 40.5°N latitude, the features have a dome-like morphology, and south of that latitude, the morphology is more cone-like. Layering is apparent in the summit craters of fresher looking southern cones, and asymmetric aprons were observed in some instances. Some of the northern domes also display layering in their summit craters, but asymmetric aprons were not observed. The northern domes can also display multiple summit pits or no summit pits at all and can occur in association with higher-albedo “pancake” features. The northern domes are higher in albedo but have apparent thermal inertias that are lower than the surrounding plains. The apparent thermal inertia values of the southern cones range from values comparable to the surrounding plains to slightly lower. From the TES thermal inertia map, we infer that the thermal inertia values of the pitted cones are between those of basaltic fine dust and sand, while those of the surrounding plains are closer to that of basaltic sand. While a unique interpretation of the origin of the pitted cones is not possible with the available data, we do not find compelling evidence to suggest an origin related to either basaltic volcanism or ground-ice. Instead, an origin for these features through some combination of mud volcanism and evaporite deposition around geysers and/or springs is most consistent with the observations.

Published
2005
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45. Evidence from Opportunity's Microscopic Imager for water on Meridiani Planum

Author

N. Spanovich, Scott M. McLennan, Kenneth E. Herkenhoff, Justin N. Maki, Steven W. Squyres, M. Sims, Robert Sullivan, William H. Farrand, Alexander G. Hayes, Thomas J. Wdowiak, D. S. Bass, Jeffrey R. Johnson, Raymond E. Arvidson, L. A. Soderblom, Peter H. Smith, Lutz Richter, Morten Madsen, Stuart Thompson, James R Rice, James F. Bell, Douglas W. Ming, Kjartan M. Kinch, Ronald Greeley, Lisa R. Gaddis, Andrew H. Knoll, Bethany L. Ehlmann, John P. Grotzinger, Catherine M. Weitz, P. Bertelsen, Bradley L. Jolliff, Stubbe F. Hviid, Harry Y. McSween, and Patrick L. Whelley

Subjects
Meridiani Planum, Geologic Sediments, Minerals, Multidisciplinary, Extraterrestrial Environment, Outcrop, Silicates, Mineralogy, Sediment, Mars, Water, Mars Exploration Program, Ferric Compounds, Diagenesis, Soil water, Cohesion (geology), Spacecraft, Geology
Abstract

The Microscopic Imager on the Opportunity rover analyzed textures of soils and rocks at Meridiani Planum at a scale of 31 micrometers per pixel. The uppermost millimeter of some soils is weakly cemented, whereas other soils show little evidence of cohesion. Rock outcrops are laminated on a millimeter scale; image mosaics of cross-stratification suggest that some sediments were deposited by flowing water. Vugs in some outcrop faces are probably molds formed by dissolution of relatively soluble minerals during diagenesis. Microscopic images support the hypothesis that hematite-rich spherules observed in outcrops and soils also formed diagenetically as concretions.

Published
2004

46. Potential Transport of Windblown Sand: Influence of Surface Roughness and Assessment with Radar Data

Author

Ronald Greeley, Lisa R. Gaddis, R. Stephen Saunders, Stephen D. Wall, James D. Iversen, Nicholas Lancaster, Anthony R. Dobrovolskis, Keld Rømer Rasmussen, Bruce R. White, and Dan G. Blumberg

Subjects
Soil science, Wind speed, law.invention, Wavelength, Boundary layer, Wind profile power law, Flux (metallurgy), Geography, law, Surface roughness, Aeolian processes, Radar, Geomorphology, Physics::Atmospheric and Oceanic Physics
Abstract

The transport of windblown sand is controlled by many factors, including wind regime and sediment supply. Surface roughness at the sub-meter scale is also important because it influences both the threshold conditions for particle entrainment and the flux of sand once it is set into motion. In general, increases in surface roughness result in higher threshold speeds for particle movement and decreases in sand fluxes. Aerodynamic roughness (z 0) is the aeolian parameter related to surface roughness and is defined as the height above some mean level at which average wind speed is zero. Values of z 0 are derived from wind measurements through the boundary layer, but few z 0 values have been obtained over natural surfaces because of the expense and limitations of making such measurements. Rather, remote sensing using radar systems has the potential for addressing this problem. In this investigation, we derived z 0 values for a wide variety of surfaces in the southwestern United States and obtained radar data for these sites in P-band (wavelength = 68 cm), L-band (wavelength = 24 cm) and C-band (wavelength = 5.6 cm). We show that there are good correlations among z 0, the RMS height of the surface, and the radar backscatter coefficient, σ0, with the best correlation for L-band HV polarized radar data. This study shows the potential for mapping large regions with radar in order to derive aerodynamic roughness values, which in turn can be used in predictive models of sand transport.

Published
1995
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47. Progress on archiving, delivering, and working with planetary data

Author

Ross A. Beyer, Lisa R. Gaddis, and Trent M. Hare

Subjects
Software, Planetary science, business.industry, Computer science, Download, Volume (computing), General Earth and Planetary Sciences, Petabyte, business, Data science, Boom, Planetary Data System, Visualization
Abstract

Planetary Data: A Workshop for Users and Software Developers 2012; Flagstaff, Ariz., 25–29 June 2012 The recent boom in the volume of data returned by planetary science missions continues to delight and confound users. Recently the NASA Planetary Data System (PDS) has seen an approximately 50-fold increase in the amount of archived data and now serves nearly half a petabyte. Within 5 years, this volume likely will approach 1 petabyte. While archivists, users, and developers have done a creditable job of providing search and download functions and analysis and visualization tools, the wealth of data necessitates more discussion between users and developers about current limitations and desired improvements.

Published
2012
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48. Book review

Author

Lisa R. Gaddis

Subjects
Clementine (nuclear reactor), Geochemistry and Petrology, Atlas (topology), media_common.quotation_subject, Art history, Art, media_common
Published
2005
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49. Radar Remote Sensing of Planetary Surfaces

Author

Lisa R. Gaddis

Subjects
geography, geography.geographical_feature_category, biology, Venus, biology.organism_classification, Astrobiology, law.invention, Planetary science, Volcano, law, Radar imaging, General Earth and Planetary Sciences, Radar remote sensing, Radar, Geology, Remote sensing
Abstract

Radar has been recognized as a practical tool for Earth and planetary science for more than 30 years. In recent years, radar images from orbiting platforms have provided spectacular views of features as diverse as volcanoes in Guatemala, buried river channels in the Egyptian desert, and the surface of Venus. Each of these features is commonly obscured by clouds or dust and had been difficult or impossible to see with other methods.

Published
2002
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50. Higher than Everest: An Adventurer's Guide to the Solar System and Turn Right at Orion: Travels through the Cosmos

Author

Lisa R. Gaddis

Subjects
Solar System, Planetary science, Olympus Mons, Extraterrestrial life, General Earth and Planetary Sciences, Art history, Mars Exploration Program, Adventure, Parallels, Geology, Astrobiology, Copernicus
Abstract

A little light reading is desirable now and then, especially over the holidays and/or during times of stress or periods of reflection. With this idea in mind, I reviewed two books that may be viewed as “science entertainment.” The first is Higher than Everest by Paul Hodge. Set some 200 years in the future, this book is structured as a guidebook for adventurers who are looking for thrills and spills at spectacular sites in the Solar System. Based on undergraduate-level lectures in planetary science, the book has 20 chapters focusing on sites such as Olympus Mons and Valles Marineris, Mars; Copernicus Crater on the Moon; Maxwell Montes, Venus; Euboea Montes, Io; and geysers on Triton. With a “peak bagging” emphasis on exploring the highest (or lowest) features, recommendations are provided for siting base camps, including necessary equipment, recognizing environmental constraints, and mapping out traverses and itineraries. Along the way, participants are advised to keep an eye out for aspects of their surroundings that would help to resolve long-standing “mysteries” regarding their origin. Parallels are drawn between extraterrestrial features and their terrestrial counterparts, and numerous photos are provided to reinforce the similarities among planetary surfaces in different environments.

Published
2002
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