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1. Impact Cratering of Mercury

Author

Caleb I. Fassett, Lillian R. Ostrach, William J. Merline, Clark R. Chapman, Robert G. Strom, Olivier S. Barnouin, Louise M. Prockter, Simone Marchi, and David M.H. Baker

Subjects
Impact crater, chemistry, Environmental chemistry, chemistry.chemical_element, Geology, Mercury (element)
Published
2018

2. The Geologic History of Mercury

Author

B. W. Denevi, Mark S. Robinson, Carolyn M. Ernst, and Louise M. Prockter

Subjects
chemistry, Geologic history, Geochemistry, chemistry.chemical_element, Geology, Mercury (element)
Published
2018

3. Stratigraphy of the Caloris basin, Mercury: Implications for volcanic history and basin impact melt

Author

Louise M. Prockter, Gregory A. Neumann, Brett W. Denevi, James W. Head, Christian Klimczak, Carolyn M. Ernst, Thomas R. Watters, Mark S. Robinson, Nancy L. Chabot, Olivier S. Barnouin, Sean C. Solomon, and Scott L. Murchie

Subjects
geography, geography.geographical_feature_category, Geochemistry, chemistry.chemical_element, Astronomy and Astrophysics, Crust, Volcanism, Structural basin, Mercury (element), Impact crater, chemistry, Volcano, Space and Planetary Science, Tectonic deformation, Geology, Single layer
Abstract

Caloris basin, Mercury's youngest large impact basin, is filled by volcanic plains that are spectrally distinct from surrounding material. Post-plains impact craters of a variety of sizes populate the basin interior, and the spectra of the material they have excavated enable the thickness of the volcanic fill to be estimated and reveal the nature of the subsurface. The thickness of the interior volcanic plains is consistently at least 2.5 km, reaching 3.5 km in places, with thinner fill toward the edge of the basin. No systematic variations in fill thickness are observed with long-wavelength topography or azimuth. The lack of correlation between plains thickness and variations in elevation at large horizontal scales within the basin indicates that plains emplacement must have predated most, if not all, of the changes in long-wavelength topography that affected the basin. There are no embayed or unambiguously buried (ghost) craters with diameters greater than 10 km in the Caloris interior plains. The absence of such ghost craters indicates that one or more of the following scenarios must hold: the plains are sufficiently thick to have buried all evidence of craters that formed between the Caloris impact event and the emplacement of the plains; the plains were emplaced soon after basin formation; or the complex tectonic deformation of the basin interior has disguised wrinkle-ridge rings localized by buried craters. That low-reflectance material (LRM) was exposed by every impact that penetrated through the surface volcanic plains provides a means to explore near-surface stratigraphy. If all occurrences of LRM are derived from a single layer, the subsurface LRM deposit is at least 7.5-8.5 km thick and its top likely once made up the Caloris basin floor. The Caloris-forming impact would have generated a layer of impact melt 3-15 km thick; such a layer could account for the entire thickness of LRM. This material would have been derived from a combination of lower crust and upper mantle.

Published
2015

4. Exogenic controls on sulfuric acid hydrate production at the surface of Europa

Author

Louise M. Prockter, L. W. Kamp, T. A. Cassidy, Chris Paranicas, James H. Shirley, and J. B. Dalton

Subjects
Inorganic chemistry, Flux, chemistry.chemical_element, Astronomy and Astrophysics, Weathering, Sulfuric acid, Sulfur, Ion, Astrobiology, Jupiter, chemistry.chemical_compound, chemistry, Space and Planetary Science, Sulfate, Hydrate
Abstract

External agents have heavily weathered the visible surface of Europa. Internal and external drivers competing to produce the surface we see include, but are not limited to: aqueous alteration of materials within the icy shell, initial emplacement of endogenic material by geologic activity, implantation of exogenic ions and neutrals from Jupiter's magnetosphere, alteration of surface chemistry by radiolysis and photolysis, impact gardening of upper surface layers, and redeposition of sputtered volatiles. Separating the influences of these processes is critical to understanding the surface and subsurface compositions at Europa. Recent investigations have applied cryogenic reflectance spectroscopy to Galileo Near-Infrared Mapping Spectrometer (NIMS) observations to derive abundances of surface materials including water ice, hydrated sulfuric acid, and hydrated sulfate salts. Here we compare derived sulfuric acid hydrate (H2SO4·nH2O) abundance with weathering patterns and intensities associated with charged particles from Jupiter's magnetosphere. We present models of electron energy, ion energy, and sulfur ion number flux as well as the total combined electron and ion energy flux at the surface to estimate the influence of these processes on surface concentrations, as a function of location. We found that correlations exist linking both electron energy flux (r∼0.75) and sulfur ion flux (r=0.93) with the observed abundance of sulfuric acid hydrate on Europa. Sulfuric acid hydrate production on Europa appears to be limited in some regions by a reduced availability of sulfur ions, and in others by insufficient levels of electron energy. The energy delivered by sulfur and other ions has a much less significant role. Surface deposits in regions of limited exogenic processing are likely to bear closest resemblance to oceanic composition. These results will assist future efforts to separate the relative influence of endogenic and exogenic sources in establishing the surface composition.

Published
2013

5. The origin of graben and ridges in Rachmaninoff, Raditladi, and Mozart basins, Mercury

Author

Louise M. Prockter, Paul K. Byrne, Christian Klimczak, D. M. Blair, Andrew M. Freed, H. Jay Melosh, Sean C. Solomon, Carolyn M. Ernst, and Maria T. Zuber

Subjects
geography, geography.geographical_feature_category, chemistry.chemical_element, Structural basin, Mercury (element), Graben, Tectonics, Horst and graben, Plate tectonics, Geophysics, Volcano, chemistry, Impact crater, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Petrology, Geomorphology, Geology
Abstract

the basin floor, and (3) subsidence following volcanic loading. Our results suggest that only thermal contraction can account for the observed pattern of graben, whereas some combination of subsidence and global contraction is the most likely explanation for the central ridges in Rachmaninoff and Mozart. Thermal contraction models, however, predict the formation of graben in the centermost region of each basin, where no graben are observed. We hypothesize that graben in this region were buried by a thin, late-stage flow of plains material, and images of partially filled graben provide evidence of such late-stage plains emplacement. These results suggest that the smooth plains units in these three basins are volcanic in origin. The thermal contraction models also imply a cooling unit ~1km thick near the basin center, further supporting the view that plains-forming lavas on Mercury were often of sufficiently high volume and low viscosity to pool to substantial thicknesses within basins and craters.

Published
2013

6. The morphology of craters on Mercury: Results from MESSENGER flybys

Author

Robert R. Herrick, Maria T. Zuber, Scott L. Murchie, Louise M. Prockter, Gregory A. Neumann, Olivier S. Barnouin, David E. Smith, and John E. Chappelow

Subjects
geography, geography.geographical_feature_category, Mercury laser, education, Mineralogy, chemistry.chemical_element, Astronomy and Astrophysics, Dual imaging, Mercury (element), Impact crater, Volcano, chemistry, Space and Planetary Science, Planet, Altimeter, Geology
Abstract

Topographic data measured from the Mercury Laser Altimeter (MLA) and the Mercury Dual Imaging System (MDIS) aboard the MESSENGER spacecraft were used for investigations of the relationship between depth and diameter for impact craters on Mercury. Results using data from the MESSENGER flybys of the innermost planet indicate that most of the craters measured with MLA are shallower than those previously measured by using Mariner 10 images. MDIS images of these same MLA-measured craters show that they have been modified. The use of shadow measurement techniques, which were found to be accurate relative to the MLA results, indicate that both small bowl-shaped and large complex craters that are fresh possess depth-to-diameter ratios that are in good agreement with those measured from Mariner 10 images. The preliminary data also show that the depths of modified craters are shallower relative to fresh ones, and might provide quantitative estimates of crater in-filling by subsequent volcanic or impact processes. The diameter that defines the transition from simple to complex craters on Mercury based on MESSENGER data is consistent with that reported from Mariner 10 data.

Published
2012

7. Mercury crater statistics from MESSENGER flybys: Implications for stratigraphy and resurfacing history

Author

William J. Merline, Louise M. Prockter, Caleb I. Fassett, Clark R. Chapman, Sean C. Solomon, Maria E. Banks, Jeffrey A. Forde, Robert G. Strom, and James W. Head

Subjects
education.field_of_study, geography, geography.geographical_feature_category, Population, chemistry.chemical_element, Astronomy and Astrophysics, Geophysics, Volcanism, Structural basin, Mercury (element), Paleontology, chemistry, Volcano, Impact crater, Space and Planetary Science, Geologic history, education, Late Heavy Bombardment, Geology
Abstract

The primary crater population on Mercury has been modified by volcanism and secondary craters. Two phases of volcanism are recognized. One volcanic episode that produced widespread intercrater plains occurred during the period of the Late Heavy Bombardment and markedly altered the surface in many areas. The second episode is typified by the smooth plains interior and exterior to the Caloris basin, both of which have a different crater size-frequency distribution than the intercrater plains, consistent with a cratering record dominated by a younger population of impactors. These two phases may have overlapped as parts of a continuous period of volcanism during which the volcanic flux tended to decrease with time. The youngest age of smooth plains volcanism cannot yet be determined, but at least small expanses of plains are substantially younger than the plains associated with the Caloris basin. The spatial and temporal variations of volcanic resurfacing events can be used to reconstruct Mercury's geologic history from images and compositional and topographic data to be acquired during the orbital phase of the MESSENGER mission.

Published
2011

8. Eminescu impact structure: Insight into the transition from complex crater to peak-ring basin on Mercury

Author

James W. Head, Louise M. Prockter, Scott L. Murchie, Sean C. Solomon, David M.H. Baker, Samuel C. Schon, and Carolyn M. Ernst

Subjects
geography, geography.geographical_feature_category, Geochemistry, chemistry.chemical_element, Astronomy and Astrophysics, Volcanism, Geophysics, Structural basin, Geologic map, Complex crater, Mercury (element), chemistry, Impact crater, Volcano, Space and Planetary Science, Impact structure, Geology
Abstract

Peak-ring basins represent an impact-crater morphology that is transitional between complex craters with central peaks and large multi-ring basins. Therefore, they can provide insight into the scale dependence of the impact process. Here the transition with increasing crater diameter from complex craters to peak-ring basins on Mercury is assessed through a detailed analysis of Eminescu, a geologically recent and well-preserved peak-ring basin. Eminescu has a diameter (∼125 km) close to the minimum for such crater forms and is thus representative of the transition. Impact crater size-frequency distributions and faint rays indicate that Eminescu is Kuiperian in age, geologically younger than most other basins on Mercury. Geologic mapping of basin interior units indicates a distinction between smooth plains and peak-ring units. Our mapping and crater retention ages favor plains formation by impact melt rather than post-impact volcanism, but a volcanic origin for the plains cannot be excluded if the time interval between basin formation and volcanic emplacement was less than the uncertainty in relative ages. The high-albedo peak ring of Eminescu is composed of bright crater-floor deposits (BCFDs, a distinct crustal unit seen elsewhere on Mercury) exposed by the impact. We use our observations to assess predictions of peak-ring formation models. We interpret the characteristics of Eminescu as consistent with basin formation models in which a melt cavity forms during the impact formation of craters at the transition to peak ring morphologies. We suggest that the smooth plains were emplaced via impact melt expulsion from the central melt cavity during uplift of a peak ring composed of BCFD-type material. In this scenario the ringed cluster of peaks resulted from the early development of the melt cavity, which modified the central uplift zone.

Published
2011

9. The transition from complex crater to peak-ring basin on Mercury: New observations from MESSENGER flyby data and constraints on basin formation models

Author

Sean C. Solomon, Brett W. Denevi, Scott L. Murchie, Samuel C. Schon, Louise M. Prockter, Carolyn M. Ernst, David M.H. Baker, Robert G. Strom, and James W. Head

Subjects
education.field_of_study, Solar System, fungi, Population, chemistry.chemical_element, Astronomy and Astrophysics, Geophysics, Structural basin, humanities, Complex crater, Physics::Geophysics, Mercury (element), Paleontology, Impact crater, chemistry, Space and Planetary Science, Planet, Physics::Space Physics, Terrestrial planet, Astrophysics::Earth and Planetary Astrophysics, education, geographic locations, Physics::Atmospheric and Oceanic Physics, Geology
Abstract

The study of peak-ring basins and other impact crater morphologies transitional between complex craters and multi-ring basins is important to our understanding of the mechanisms for basin formation on the terrestrial planets. Mercury has the largest population, and the largest population per area, of peak-ring basins and protobasins in the inner solar system and thus provides important data for examining questions surrounding peak-ring basin formation. New flyby images from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft have more than doubled the area of Mercury viewed at close range, providing nearly complete global coverage of the planet's surface when combined with flyby data from Mariner 10. We use this new near-global dataset to compile a catalog of peak-ring basins and protobasins on Mercury, including measurements of the diameters of the basin rim crest, interior ring, and central peak (if present). Our catalog increases the population of peak-ring basins by ∼150% and protobasins by ∼100% over previous catalogs, including 44 newly identified peak-ring basins (total=74) and 17 newly identified protobasins (total=32). A newly defined transitional basin type, the ringed peak-cluster basin (total=9), is also described. The new basin catalog confirms that Mercury has the largest population of peak-ring basins of the terrestrial planets and also places the onset rim-crest diameter for peak-ring basins at 126 − 26 + 33 km , which is intermediate between the onset diameter for peak-ring basins on the Moon and those for the other terrestrial planets. The ratios of ring diameter to rim-crest diameter further emphasize that protobasins and peak-ring basins are parts of a continuum of basin morphologies relating to their processes of formation, in contrast to previous views that these forms are distinct. Comparisons of the predictions of peak-ring basin-formation models with the characteristics of the basin catalog for Mercury suggest that formation and modification of an interior melt cavity and nonlinear scaling of impact melt volume with crater diameter provide important controls on the development of peak rings. The relationship between impact-melt production and peak-ring formation is strengthened further by agreement between power laws fit to ratios of ring diameter to rim-crest diameter for peak-ring basins and protobasins and the power-law relation between the dimension of a melt cavity and the crater diameter. More detailed examination of Mercury's peak-ring basins awaits the planned insertion of the MESSENGER spacecraft into orbit about Mercury in 2011.

Published
2011

10. Flood Volcanism in the Northern High Latitudes of Mercury Revealed by MESSENGER

Author

D. M. Hurwitz, Jeffrey J. Gillis-Davis, Nancy L. Chabot, William J. Merline, Sean C. Solomon, David T. Blewett, Clark R. Chapman, Louise M. Prockter, Thomas R. Watters, Caleb I. Fassett, Lillian R. Ostrach, James L. Dickson, Larry R. Nittler, Scott L. Murchie, Jennifer L. Whitten, Robert G. Strom, Zhiyong Xiao, James W. Head, Christian Klimczak, Brett W. Denevi, David M.H. Baker, Carolyn M. Ernst, Jürgen Oberst, Laura Kerber, Paul K. Byrne, and Timothy A. Goudge

Subjects
Basalt, geography, Multidisciplinary, geography.geographical_feature_category, Flood myth, Landform, Messenger, Geochemistry, chemistry.chemical_element, Mercury, Volcanism, Mercury (element), Latitude, chemistry, Impact crater, Planet, Geology
Abstract

MESSENGER observations from Mercury orbit reveal that a large contiguous expanse of smooth plains covers much of Mercury's high northern latitudes and occupies more than 6% of the planet's surface area. These plains are smooth, embay other landforms, are distinct in color, show several flow features, and partially or completely bury impact craters, the sizes of which indicate plains thicknesses of more than 1 kilometer and multiple phases of emplacement. These characteristics, as well as associated features, interpreted to have formed by thermal erosion, indicate emplacement in a flood-basalt style, consistent with x-ray spectrometric data indicating surface compositions intermediate between those of basalts and komatiites. The plains formed after the Caloris impact basin, confirming that volcanism was a globally extensive process in Mercury's post-heavy bombardment era.

Published
2011

11. A message from Mercury

Author

Louise M. Prockter

Subjects
chemistry, Environmental chemistry, General Physics and Astronomy, Environmental science, chemistry.chemical_element, Mercury (element)
Published
2011

12. Europa’s ridged plains and smooth low albedo plains: Distinctive compositions and compositional gradients at the leading side–trailing side boundary

Author

Louise M. Prockter, L. W. Kamp, J. B. Dalton, and James H. Shirley

Subjects
Mirabilite, Meteorology, Sulfur cycle, Mineralogy, Astronomy and Astrophysics, Sulfuric acid, Charged particle, chemistry.chemical_compound, Wavelength, chemistry, Space and Planetary Science, Absorption band, Hydrate, Relative species abundance, Geology
Abstract

This investigation uses linear mixture modeling employing cryogenic laboratory reference spectra to estimate surface compositions and water ice grain sizes of Europa’s ridged plains and smooth low albedo plains. Near-infrared spectra for 23 exposures of ridged plains materials are analyzed along with 11 spectra representing low albedo plains. Modeling indicates that these geologic units differ both in the relative abundance of non-ice hydrated species and in the abundance and grain sizes of water ice. The background ridged plains in our study area appear to consist predominantly of water ice (∼46%) with approximately equal amounts (on average) of hydrated sulfuric acid (∼27%) and hydrated salts (∼27%). The solutions for the smooth low albedo plains are dominated by hydrated salts (∼62%), with a relatively low mean abundance of water ice (∼10%), and an abundance of hydrated sulfuric acid similar to that found in ridged plains (∼27%). The model yields larger water ice grain sizes (100 μm versus 50–75 μm) in the ridged plains. The 1.5-μm water ice absorption band minimum is found at shorter wavelengths in the low albedo plains deposits than in the ridged plains (1.498 ± .003 μm versus 1.504 ± .001 μm). The 2.0-μm band minimum in the low albedo plains exhibits a somewhat larger blueshift (1.964 ± .006 μm versus 1.983 ± .006 μm for the ridged plains). The study area spans longitudes from 168° to 185°W, which includes Europa’s leading side–trailing side boundary. A well-defined spatial gradient of sulfuric acid hydrate abundance is found for both geologic units, with concentrations increasing in the direction of the trailing side apex. We associate this distribution with the exogenic effects of magnetospheric charged particle bombardment and associated chemical processing of surface materials (the radiolytic sulfur cycle). However, one family of low albedo plains exposures exhibits sulfuric acid hydrate abundances up to 33% lower than found for adjacent exposures, suggesting that these materials have undergone less processing, thus implying that these deposits may have been emplaced more recently. Modeling identifies high abundances (to 30%) of magnesium sulfate brines in the low albedo plains exposures. Our investigation marks the first spectroscopic identification of MgSO4 brine on Europa. We also find significantly higher abundances of sodium-bearing species (bloedite and mirabilite) in the low albedo plains. The results illuminate the role of radiolytic processes in modifying the surface composition of Europa, and may provide new constraints for models of the composition of Europa’s putative subsurface ocean.

Published
2010

13. The Study of Mercury

Author

Louise M. Prockter and Peter D. Bedini

Subjects
Physics, Spacecraft, business.industry, media_common.quotation_subject, chemistry.chemical_element, Astronomy, Astronomy and Astrophysics, Celestial mechanics, Mercury (element), Astrobiology, chemistry, Space and Planetary Science, Planet, Sky, business, Scientific study, Space environment, media_common
Abstract

When the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft enters orbit about Mercury in March 2011 it will begin a new phase in an age-old scientific study of the innermost planet. Despite being visible to the unaided eye, Mercury's proximity to the Sun makes it extremely difficult to observe from Earth. Nonetheless, over the centuries man has pursued a quest to understand the elusive planet, and has teased out information about its motions in the sky, its relation to the other planets, and its physical characteristics. A great leap was made in our understanding of Mercury when the Mariner 10 spacecraft flew past it three times in the mid-1970s, providing a rich set of close-up observations. Now, three decades later, The MESSENGER spacecraft has also visited the planet three times, and is poised to add significantly to the study with a year-long orbital observation campaign.

Published
2010

14. Large impact basins on Mercury: Global distribution, characteristics, and modification history from MESSENGER orbital data

Author

Caleb I. Fassett, Robert G. Strom, James W. Head, Clark R. Chapman, David M.H. Baker, Roger J. Phillips, Louise M. Prockter, Maria T. Zuber, David E. Smith, Frank Preusker, Sean C. Solomon, Christian Klimczak, Gregory A. Neumann, and Jürgen Oberst

Subjects
Atmospheric Science, Earth science, Population, Soil Science, chemistry.chemical_element, Volcanism, Aquatic Science, Structural basin, Oceanography, Paleontology, Geochemistry and Petrology, Planet, Earth and Planetary Sciences (miscellaneous), education, Late Heavy Bombardment, Earth-Surface Processes, Water Science and Technology, education.field_of_study, Ecology, fungi, Forestry, Volcanology, humanities, Mercury (element), Geophysics, chemistry, Space and Planetary Science, Global distribution, geographic locations, Geology
Abstract

The formation of large impact basins (diameter D greater than or equal to 300 km) was an important process in the early evolution of Mercury and influenced the planet's topography, stratigraphy, and crustal structure. We catalog and characterize this basin population on Mercury from global observations by the MESSENGER spacecraft, and we use the new data to evaluate basins suggested on the basis of the Mariner 10 flybys. Forty-two certain or probable impact basins are recognized a few additional basins that may have been degraded to the point of ambiguity are plausible on the basis of new data but are classified as uncertain. The spatial density of large basins (D greater than or equal to 500 km) on Mercury is lower than that on the Moon. Morphological characteristics of basins on Mercury suggest that on average they are more degraded than lunar basins. These observations are consistent with more efficient modification, degradation, and obliteration of the largest basins on Mercury than on the Moon. This distinction may be a result of differences in the basin formation process (producing fewer rings), greater relaxation of topography after basin formation (subduing relief), and/or higher rates of volcanism during the period of heavy bombardment on Mercury compared to the Moon (burying basin rings and interiors).

Published
2012

15. The effects of the target material properties and layering on the crater chronology: The case of Raditladi and Rachmaninoff basins on Mercury

Author

Elena Martellato, Lorenza Giacomini, Louise M. Prockter, Matteo Massironi, Simone Marchi, and Gabriele Cremonese

Subjects
Geochemistry, chemistry.chemical_element, FOS: Physical sciences, Terrain, Structural basin, Age determination, Craters, Impact crater, Rachmaninoff basin, Earth and Planetary Astrophysics (astro-ph.EP), geography, geography.geographical_feature_category, Raditladi basin, Astronomy and Astrophysics, Mercury, humanities, Mercury (element), Young age, chemistry, Volcano, Space and Planetary Science, Layering, Geology, Chronology, Astrophysics - Earth and Planetary Astrophysics
Abstract

In this paper we present a crater age determination of several terrains associated with the Raditladi and Rachmaninoff basins. These basins were discovered during the first and third MESSENGER flybys of Mercury, respectively. One of the most interesting features of both basins is their relatively fresh appearance. The young age of both basins is confirmed by our analysis on the basis of age determination via crater chronology. The derived Rachmaninoff and Raditladi basin model ages are about 3.6 Ga and 1.1 Ga, respectively. Moreover, we also constrain the age of the smooth plains within the basins' floors. This analysis shows that Mercury had volcanic activity until recent time, possibly to about 1 Ga or less. We find that some of the crater size-frequency distributions investigated suggest the presence of a layered target. Therefore, within this work we address the importance of considering terrain parameters, as geo-mechanical properties and layering, into the process of age determination. We also comment on the likelihood of the availability of impactors able to form basins with the sizes of Rachmaninoff and Raditladi in relatively recent times., Accepted by PSS, to appear on MESSENGER Flybys special issue

Published
2011

17. MESSENGER at Mercury

Author

David T. Blewett, Sean C. Solomon, and Louise M. Prockter

Subjects
Geophysics, Planetary science, chemistry, Space and Planetary Science, Geochemistry and Petrology, Earth science, Earth and Planetary Sciences (miscellaneous), chemistry.chemical_element, Geology, Mercury (element), Astrobiology
Published
2009

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