Kuiper Quadrangle Spectral Analysis: Looking Forward to Integrated Geological Map

Total Page:16

File Type:pdf, Size:1020Kb

Kuiper Quadrangle Spectral Analysis: Looking Forward to Integrated Geological Map EPSC Abstracts Vol. 14, EPSC2020-367, 2020 https://doi.org/10.5194/epsc2020-367 Europlanet Science Congress 2020 © Author(s) 2021. This work is distributed under the Creative Commons Attribution 4.0 License. Kuiper Quadrangle spectral analysis: looking forward to integrated geological map Cristian Carli1, Lorenza Giacomini1, Francesca Zambon1, Sabrina Ferrari2, Matteo Massironi3, Valentina Galluzzi1, Francesca Altieri1, Fabrizio Capaccioni1, Luigi Ferranti4, and Pasquale Palumbo1,5 1INAF-IAPS, Rome, Italy 2CISAS “G.Colombo”, Università degli Studi di Padova, Padua, Italy 3Dipartimento di Geoscienze, Università degli Studi di Padova, Padua, Italy 4DISTAR, Università degli Studi di Napoli Federico II, Naples, Italy 5Dipartimento di Scienze & Tecnologie, Università degli Studi di Napoli ‘Parthenope’, Naples, Italy. Mercury geology reached a new era after the MESSENGER mission, which has allowed not only to acquire global information but also to study the geological history of the planet with multiple techniques. The orbital BepiColombo mission will be the next step to fix some of the Hermean paradigm because more techniques, coupled with the higher resolution of the instruments onboard Mio and Bepi. Integration of compositional data and morpho-stratigraphic maps generally produced from camera data, will be one of the main issue to improve the understanding of Mercury geological evolution. This goal is also correlated with the efforts of other projects such as PLANMAP European H2020 and GMAP Europlanet 20-24. Several morpho-stratigraphic maps of Mercury quadrangles have been produced, or are ongoing (e.g. Galluzzi et al. 2018), and a global map has been realized (e.g. Kinczyk et al. 2019). Discussion or integration at quadrangle level of Mercury is recently beginning (e.g. Bott et al. 2019; Zambon et al. 2019) and here we report activity done in the Kuiper H06. Kuiper (H06) is an equatorial quadrangle, and it encompasses the area between longitudes 72°W –0° and latitudes 22.5°N – 22.5°S. H06 morpho-stratigraphic mapping is still ongoing (Giacomini et al. 2018; 2019), it evidences a high variegation of units, from older intercrater plains to younger smooth plains, to craters. Several craters show pyroclastic deposits (e.g. Kerber et al. 2011; Pajola et al. 2020), in some cases with putative vents, and hollows. Some of the hollows look like very peculiar from spectral point of view, e.g. in Dominici Crater (Vilas et al. 2016; Lucchetti et al. 2018), showing possible indication of mineralogical phases. Whereas most smooth plains are limited in extension and confined on the floor of the largest craters, a wide smooth plain has been detected that surrounds Rudaki crater. Some of these plains show clearly color variegation (e.g. two color units within Renoir Basin, see Giacomini et al. 2018). Due to the low latitudes, the coverage from MDIS data with high spatial resolution is lower than the northern quadrangles (e.g. Bott et al. 2019; Zambon et al. 2019) and we approach the study in a multiple-stage passages. This has been done to investigate the region with the best detail from a spectral point of view. Following the mosaic product procedure used by Zambon et al. (2019), we generate a homogeneous 8 color global mosaic at 1600 m/px scale (average scale taking into account the average resolution) and at 665 m/px pushing the resolution. Moreover, we considered the partial quadrangle coverage mosaics at 385 m/px and 246 m/px to exploit the presence of higher resolution color images. We will show spectral variations considering specific indices and color combinations (example on Figure 1), discussing the possibility to define some spectral units which could be later integrated with the morpho-stratigraphic mapping. Furthermore, we will locally investigate the spectral variation of specific cases, e.g. fresh craters, hollows and pyroclastic material, to infer some indication on material composition, or within some blue dark regions to understand the possible darkening material. This activity could be also helpful in the definition of indicators improving the selection procedure for regions of interest (see also Giacomini et al. 2020) to be studied for covering the science goals of the BepiColombo mission (e.g. Rothery et al. 2020). Acknowledgements: We gratefully acknowledge funding from the Italian Space Agency (ASI) under ASI-INAF agreement 2017-47-H.0. MM, CC, FZ, FA were also supported by European Union’s Horizon 2020 research grant agreement No 776276- PLANMAP. MM, CC, FA were also supported by Europlanet 20-24 GMAP, EPN- RI-2024. References: Bott N., et al. 2019. Global Spectral Properties and Lithology of Mercury: The Example of the Shakespeare (H‐03) Quadrangle. JGR-Planets, 124, 2326-2346. Zambon F., et al. 2019. Spectral properties of the H05 Hokusai quadrangle on Mercury and relationship with the morpho-stratigraphic units. EGU 7796. Giacomini L., et al. 2018. Updates on geologic mapping of Kuiper (H06) quadrangle. EPSC 721-1. Giacomini L., et al. 2019. GEOLOGICAL MAPPING OF THE KUIPER (H06) QUADRANGLE OF MERCURY. XV Congresso delle Scienze Planetarie, pg. 71. Giacomini L., et al. 2020. Scientific sites of interest in Kuiper Quadrangle (H06). EPSC this meeting. Kerber L., et al. 2011. The global distribution of pyroclastic deposits on Mercury: The view from MESSENGER flybys 1–3. PSS, 59, 1895–1909. Kinczyk M.J., et al. 2019. The First Global Geological Map of Mercury. EPSC-DPS 1045-1. Lucchetti A., et al. 2018. Mercury Hollows as Remnants of Original Bedrock Materials and Devolatilization Processes: A Spectral Clustering and Geomorphological Analysis. JGR-Planets, 123, 2365-2379. Pajola M., et al. 2020. MULTIDISCIPLINARY ANALYSIS OF LERMONTOV CRATER ON MERCURY. 51 LPSC 1402. Rothery et al. 2020. Rationale for BepiColombo studies of Mercury’s surface and composition. Spa.Sci.Review. in press. Vilas F., et al. 2016. Mineralogical indicators of Mercury's hollows composition in MESSENGER color observations. JGR 43, 1450-1456. Powered by TCPDF (www.tcpdf.org).
Recommended publications
  • Shallow Crustal Composition of Mercury As Revealed by Spectral Properties and Geological Units of Two Impact Craters
    Planetary and Space Science 119 (2015) 250–263 Contents lists available at ScienceDirect Planetary and Space Science journal homepage: www.elsevier.com/locate/pss Shallow crustal composition of Mercury as revealed by spectral properties and geological units of two impact craters Piero D’Incecco a,n, Jörn Helbert a, Mario D’Amore a, Alessandro Maturilli a, James W. Head b, Rachel L. Klima c, Noam R. Izenberg c, William E. McClintock d, Harald Hiesinger e, Sabrina Ferrari a a Institute of Planetary Research, German Aerospace Center, Rutherfordstrasse 2, D-12489 Berlin, Germany b Department of Geological Sciences, Brown University, Providence, RI 02912, USA c The Johns Hopkins University Applied Physics Laboratory, Laurel, MD 20723, USA d Laboratory for Atmospheric and Space Physics, University of Colorado, Boulder, CO 80303, USA e Westfälische Wilhelms-Universität Münster, Institut für Planetologie, Wilhelm-Klemm Str. 10, D-48149 Münster, Germany article info abstract Article history: We have performed a combined geological and spectral analysis of two impact craters on Mercury: the Received 5 March 2015 15 km diameter Waters crater (106°W; 9°S) and the 62.3 km diameter Kuiper crater (30°W; 11°S). Using Received in revised form the Mercury Dual Imaging System (MDIS) Narrow Angle Camera (NAC) dataset we defined and mapped 9 October 2015 several units for each crater and for an external reference area far from any impact related deposits. For Accepted 12 October 2015 each of these units we extracted all spectra from the MESSENGER Atmosphere and Surface Composition Available online 24 October 2015 Spectrometer (MASCS) Visible-InfraRed Spectrograph (VIRS) applying a first order photometric correc- Keywords: tion.
    [Show full text]
  • Case Fil Copy
    NASA TECHNICAL NASA TM X-3511 MEMORANDUM CO >< CASE FIL COPY REPORTS OF PLANETARY GEOLOGY PROGRAM, 1976-1977 Compiled by Raymond Arvidson and Russell Wahmann Office of Space Science NASA Headquarters NATIONAL AERONAUTICS AND SPACE ADMINISTRATION • WASHINGTON, D. C. • MAY 1977 1. Report No. 2. Government Accession No. 3. Recipient's Catalog No. TMX3511 4. Title and Subtitle 5. Report Date May 1977 6. Performing Organization Code REPORTS OF PLANETARY GEOLOGY PROGRAM, 1976-1977 SL 7. Author(s) 8. Performing Organization Report No. Compiled by Raymond Arvidson and Russell Wahmann 10. Work Unit No. 9. Performing Organization Name and Address Office of Space Science 11. Contract or Grant No. Lunar and Planetary Programs Planetary Geology Program 13. Type of Report and Period Covered 12. Sponsoring Agency Name and Address Technical Memorandum National Aeronautics and Space Administration 14. Sponsoring Agency Code Washington, D.C. 20546 15. Supplementary Notes 16. Abstract A compilation of abstracts of reports which summarizes work conducted by Principal Investigators. Full reports of these abstracts were presented to the annual meeting of Planetary Geology Principal Investigators and their associates at Washington University, St. Louis, Missouri, May 23-26, 1977. 17. Key Words (Suggested by Author(s)) 18. Distribution Statement Planetary geology Solar system evolution Unclassified—Unlimited Planetary geological mapping Instrument development 19. Security Qassif. (of this report) 20. Security Classif. (of this page) 21. No. of Pages 22. Price* Unclassified Unclassified 294 $9.25 * For sale by the National Technical Information Service, Springfield, Virginia 22161 FOREWORD This is a compilation of abstracts of reports from Principal Investigators of NASA's Office of Space Science, Division of Lunar and Planetary Programs Planetary Geology Program.
    [Show full text]
  • From Morpho-Stratigraphic to Geo(Spectro)-Stratigraphic Units: the PLANMAP Contribution
    Planetary Geologic Mappers 2021 (LPI Contrib. No. 2610) 7045.pdf From morpho-stratigraphic to geo(spectro)-stratigraphic units: the PLANMAP contribution. Matteo Massironi1, Angelo Pio Rossi2, Jack Wright3, Francesca Zambon4, Claudia Poehler5, Lorenza Giacomini4, Cristian Carli4, Sabrina Ferrari6, Andrea Semenzato7, Erica Luzzi2, Riccardo Pozzobon6, Gloria Tognon6, David A. Rothery3, Carolyn Van der Bogert5, V. Galluzzi4, Francesca Altieri4 1Department of Geosciences, University of Padova, [email protected], 2Jacobs University Bremen, 3Open University, 4INAF-IAPS, 5Westfälische-Wilhelms Universität Münster 6CISAS, University of Padova 7Engineering Ingegneria Informatica S.p.A., Venezia Introduction: From the Apollo era onward, planetary ‘geologic’ mapping has been carried out using a photo-interpretative approach mainly on panchromatic and monochromatic images. This limits the definition of geological units to morpho-stratigraphic considerations so that units have been mainly defined by their stratigraphic position, surface textures and morphology, and attribution to general emplacement processes (a few related to magmatism, some broad sedimentary environments, some diverse impact domains, and all with uncertainties of interpretation). On the other hand, geological units on Earth are defined by several Figure 1: in-series interpretation from Giacomini et al. parameters besides the stratigraphic ones, such as rock EGU 2021-15052 textures, lithology, composition, and numerous environmental conditions of their origin (diverse Contextual interpretation: Geo(spectro)- magmatic, volcanic, metamorphic and sedimentary stratigraphic maps can be also produced directly from a environments). Hence, traditional morpho-stratigraphic contextual work on black and white images and RGB maps of planets and geological maps on the Earth are color compositions either using Principal Component still separated by an important conceptual and effective (PC) analysis (see Mercury examples in Semenzato et gap.
    [Show full text]
  • Updates on Geologic Mapping of Kuiper (H06) Quadrangle
    EPSC Abstracts Vol. 12, EPSC2018-721-1, 2018 European Planetary Science Congress 2018 EEuropeaPn PlanetarSy Science CCongress c Author(s) 2018 Updates on geologic mapping of Kuiper (H06) quadrangle Lorenza Giacomini (1), Valentina Galluzzi (1), Cristian Carli (1), Matteo Massironi (2), Luigi Ferranti (3) and Pasquale Palumbo (4,1). (1) INAF, Istituto di Astrofisica e Planetologia Spaziali (IAPS), Rome, Italy ([email protected]); (2) Dipartimento di Geoscienze, Università degli Studi di Padova, Padua, Italy; (3) DISTAR, Università degli Studi di Napoli Federico II, Naples, Italy; (4) Dipartimento di Scienze & Tecnologie, Università degli Studi di Napoli ‘Parthenope’, Naples, Italy. 1. Introduction -C3 craters. They represent fresh craters with sharp rim and extended bright and rayed ejecta; Kuiper quadrangle is located at the equatorial zone of -C2 craters. Moderate degraded craters whose rim is Mercury and encompasses the area between eroded but clearly detectable. Extensive ejecta longitudes 288°E – 360°E and latitudes 22.5°N – blankets are still present; 22.5°S. The quadrangle was previously mapped for -C1 craters. Very degraded craters with an almost its most part by [2] that, using Mariner10 data, completely obliterated rim. Ejecta are very limited or produced a final 1:5M scale map of the area. In this absent. work we present the preliminary results of a more Different plain units were also identified and classified as: detailed geological map (1:3M scale) of the Kuiper - Intercrater plains. Densely cratered terrains, quadrangle that we compiled using the higher characterized by a rough surface texture. They resolution MESSENGER data. represent the more extended plains on the quadrangle; - Intermediate plains.
    [Show full text]
  • High-Resolution Topography of Mercury from Messenger Orbital Stereo Imaging – the Southern Hemisphere Quadrangles
    The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-3, 2018 ISPRS TC III Mid-term Symposium “Developments, Technologies and Applications in Remote Sensing”, 7–10 May, Beijing, China HIGH-RESOLUTION TOPOGRAPHY OF MERCURY FROM MESSENGER ORBITAL STEREO IMAGING – THE SOUTHERN HEMISPHERE QUADRANGLES F. Preusker 1 *, J. Oberst 1,2, A. Stark 1, S. Burmeister 2 1 German Aerospace Center (DLR), Institute of Planet. Research, Berlin, Germany – (stephan.elgner, frank.preusker, alexander.stark, juergen.oberst)@dlr.de 2 Technical University Berlin, Institute for Geodesy and Geoinformation Sciences, Berlin, Germany – (steffi.burmeister, juergen.oberst)@tu-berlin.de Commission VI, WG VI/4 KEY WORDS: Mercury, MESSENGER, Digital Terrain Models ABSTRACT: We produce high-resolution (222 m/grid element) Digital Terrain Models (DTMs) for Mercury using stereo images from the MESSENGER orbital mission. We have developed a scheme to process large numbers, typically more than 6000, images by photogrammetric techniques, which include, multiple image matching, pyramid strategy, and bundle block adjustments. In this paper, we present models for map quadrangles of the southern hemisphere H11, H12, H13, and H14. 1. INTRODUCTION Mercury requires sophisticated models for calibrations of focal length and distortion of the camera. In particular, the WAC The MErcury Surface, Space ENviorment, GEochemistry, and camera and NAC camera were demonstrated to show a linear Ranging (MESSENGER) spacecraft entered orbit about increase in focal length by up to 0.10% over the typical range of Mercury in March 2011 to carry out a comprehensive temperatures (-20 to +20 °C) during operation, which causes a topographic mapping of the planet.
    [Show full text]
  • Tidal Deformation of Planets and Satellites: Models and Methods for Laser- and Radar Altimetry
    Tidal Deformation of Planets and Satellites: Models and Methods for Laser- and Radar Altimetry vorgelegt von Diplom Physiker Gregor Steinbr¨ugge geb. in Berlin von der Fakult¨atVI { Planen Bauen Umwelt der Technischen Universit¨atBerlin zur Erlangung des akademischen Grades Doktor der Naturwissenschaften - Dr. rer. nat. - genehmigte Dissertation Vorsitzender: Prof. Dr. Dr. h.c. Harald Schuh Gutachter: Prof. Dr. J¨urgenOberst Gutachter: Prof. Dr. Nicolas Thomas Gutachter: Prof. Dr. Tilman Spohn Tag der wissenschaftlichen Aussprache: 27.03.2018 Berlin 2018 2 Contents Title Page 1 Contents 3 List of Figures 7 List of Tables 9 1 Introduction 15 1.1 Structure of the Dissertation . 16 1.1.1 Icy Satellites . 17 1.1.2 Mercury . 20 1.2 Theory of Tides . 21 1.2.1 Tidal Potentials . 21 1.2.2 Response of Planetary Bodies to Tidal Forces . 23 1.3 Measuring Tidal Deformations . 25 1.3.1 Measurement Concepts . 25 1.3.2 Laser Altimetry . 25 1.3.3 Radar Altimetry . 26 1.4 Missions and Instruments . 27 1.4.1 REASON and the Europa Clipper Mission . 27 1.4.2 GALA and the JUICE Mission . 28 1.4.3 BELA and the BepiColombo Mission . 29 2 Research Paper I 31 2.1 Introduction . 32 2.2 Instrument Performance Modeling . 32 2.2.1 Link Budget . 32 2.2.2 Signal-to-Noise Ratio . 33 2.3 Expected Science Performance . 37 2.3.1 Topographic Coverage . 37 2.3.2 Slope and Roughness . 37 2.4 Tidal Deformation . 40 2.4.1 Covariance Analysis . 40 2.4.2 Numerical Simulation .
    [Show full text]
  • The Southern Hemisphere
    High-resolution topography from MESSENGER orbital stereo imaging – The Southern hemisphere Frank Preusker, Jürgen Oberst, Alexander Stark, K.-D. Matz, K. Gwinner, and T. Roatsch Institute of Planetary Science – Department of Planetary Geodesy MESSENGER Mission • MErcury Surface, Space ENvironment, GEochemistry, and Ranging − Launch: 08/2004 − Flybys: 01/2008, 10/2008 and 09/2009 (Oberst et al., 2010; Preusker et al., 2011) − Orbit insertion: 03/2011 − Almost 4 years of orbit operations • One measurement goal of the mission: global/topographic mapping • Main techniques: laser ranging and stereo imaging • Due to MESSENGER’s eccentric (polar) orbit, laser altimeter tracks are widely spaced near the equator and do not cover most of the southern hemisphere EPSC 2017 – Riga/Latvia – TP2 Mercury Science and Observation MESSENGER Camera • Mercury Dual Imaging System (MDIS) acquired more than 200,000 images • Narrow Angle Camera (NAC) and Wide Angle Camera (WAC) • Imaging by WAC or NAC is to optimize coverage vs. resolution from MESSENGER’s elliptic orbit • Global (stereo) coverage at resolution better than 250 m/pixel EPSC 2017 – Riga/Latvia – TP2 Mercury Science and Observation Motivation • Global high-res topographic base map for Mercury • Complementary to MLA in the northern hemisphere • Quantitative geomorphologic analysis (impact basin morphology, tectonic etc.) • for precise ortho-image registration, mosaicking, and map generation of monochrome/color MDIS images (or other instruments, e.g. MASCS) • Preparation for ESA mission BepiColombo EPSC 2017 – Riga/Latvia – TP2 Mercury Science and Observation Processing strategy • For practical reasons the stereo-photogrammetric processing is separated into 15 tiles • Each quadrangle is covered by ~ 10,000 images, ~ 20,000 stereo image combinations • Northern hemisphere quads are used for MLA co-registration and analyses both topographic products (e.g.
    [Show full text]
  • Merging of New 1:3M Mercury Geologic Maps at Northern Mid-Latitudes: Status Report
    47th Lunar and Planetary Science Conference (2016) 2119.pdf MERGING OF NEW 1:3M MERCURY GEOLOGIC MAPS AT NORTHERN MID-LATITUDES: STATUS REPORT. V. Galluzzi1, L. Guzzetta1, P. Mancinelli2, L. Giacomini3, L. Ferranti4, M. Massironi3, P. Palumbo1,5, C. Pauselli2 and D. A. Rothery6, 1INAF, Istituto di Astrofisica e Planetologia Spaziali, Rome IT ([email protected]), 2Dipartimento di Fisica e Geologia, Università degli Studi di Perugia, Perugia IT, 3Dipartimento di Geoscienze, Università degli Studi di Padova, Padua IT, 4DiSTAR, Università degli Studi di Napoli “Federico II”, Naples IT, 5Dipartimento di Scienze e Teconologie, Università degli Studi di Napoli “Parthenope”, Naples IT, 6Department of Physical Sciences, The Open University, Milton Keynes UK. Introduction: Planetary geological mapping is key ping based on Mariner 10 images at 1:5M scale [11], to understanding planetary surface processes, dynamics covered only ~40% of the area. and age correlations. After the end of Mariner 10 mis- H03 - Shakespeare quadrangle. This quadrangle sion a 1:5M geologic map of seven of the fifteen quad- (180°E – 270°E; 22.5°N – 65°N) is almost totally cov- rangles of Mercury [1], [2] (and references therein) ered by the previous 1:5M geologic map by [12]. Cur- was produced. MESSENGER (MErcury Surface, rently, it is being mapped [13] on the same basis as the Space ENvironment, GEochemistry and Ranging) mis- work done for H02. It encompasses the eastern part of sion filled the gap by imaging 100% of the planet with the Caloris Basin and so includes all the units related to a frame resolution up to 8 mpp (meters per pixel) at the the Caloris impact event and subsequent volcanism.
    [Show full text]
  • Geology of the Hokusai Quadrangle (H05), Mercury Jack Wright, David Rothery, Matthew Balme, Susan Conway
    Geology of the Hokusai quadrangle (H05), Mercury Jack Wright, David Rothery, Matthew Balme, Susan Conway To cite this version: Jack Wright, David Rothery, Matthew Balme, Susan Conway. Geology of the Hokusai quadrangle (H05), Mercury. Journal of Maps, Taylor & Francis, 2019, 15 (2), pp.509-520. 10.1080/17445647.2019.1625821. hal-02268382 HAL Id: hal-02268382 https://hal.archives-ouvertes.fr/hal-02268382 Submitted on 20 Aug 2019 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. ! " ##$$$% & %'!# #(!)* + ", -. / & " -*0 ', '.1" 02 3&4%5 ,0 $5%6 !7 %8 $ , 9' ' !"#" $%&'()* + , ! - " $,&.) "+/!'.0%.&(.%&120 '&'&3&4'566.765%&'('7%.3%' 9 . ' !"# "$%&' () *+, ( -) &))$# ./)&0 1 &")#' '2 &)# '3) 4 5#(&)$() )# !"# &# & 2& 6"( $ ) 0# 7 &)# 4 58 ()9 )) /##(.8 & & ')00)& 0)&"' & ) 555)& ' &# &0 ( )0 & 7 &)#%&' () &:7 &)#8 ;7 ( JOURNAL OF MAPS 2019, VOL. 15, NO. 2, 509–520 https://doi.org/10.1080/17445647.2019.1625821 Science Geology of the Hokusai quadrangle (H05), Mercury Jack Wright a, David A. Rothery a, Matthew R. Balme a and Susan J. Conway b aSchool of Physical Sciences, The Open University, Milton Keynes, UK; bCNRS UMR 6112, Laboratoire de Planétologie et Géodynamique, Université de Nantes, Nantes, France ABSTRACT ARTICLE HISTORY The Hokusai (H05) quadrangle is in Mercury’s northern mid-latitudes (0–90°E, 22.5–65°N) and Received 22 February 2019 covers almost 5 million km2, or 6.5%, of the planet’s surface.
    [Show full text]
  • The Tectonics of Mercury
    P1: aaa Trim: 174mm × 247mm Top: 0.553in Gutter: 0.747in CUUK632-02 CUUK632-Watters ISBN: 978 0 521 76573 2 June 26, 2009 20:13 2 The tectonics of Mercury T. R. Watters Center for Earth and Planetary Studies, National Air and Space Museum, Smithsonian Institution, Washington and F. Nimmo Department of Earth and Planetary Sciences, University of California, Santa Cruz Summary Mercury has a remarkable number of landforms that express widespread defor- mation of the planet’s crustal materials. Deformation on Mercury can be broadly described as either distributed or basin-localized. The distributed deformation on Mercury is dominantly compressional. Crustal shortening is reflected by three land- forms, lobate scarps, high-relief ridges, and wrinkle ridges. Lobate scarps are the expression of surface-breaking thrust faults and are widely distributed on Mercury. High-relief ridges are closely related to lobate scarps and appear to be formed by high-angle reverse faults. Wrinkle ridges are landforms that reflect folding and thrust faulting and are found largely in smooth plains material within and exterior to the Caloris basin. The Caloris basin has an array of basin-localized tectonic features. Basin-concentric wrinkle ridges in the interior smooth plains material are very similar to those found in lunar mascon basins. The Caloris basin also has the only clear evidence of broad-scale, extensional deformation. Extension of the interior plains materials is expressed as a complex pattern of basin-radial and basin-concentric graben. The graben crosscut the wrinkle ridges in Caloris, suggesting that they are among the youngest tectonic features on Mercury.
    [Show full text]
  • Geological Mapping of the Kuiper Quadrangle (H06) of Mercury
    Geophysical Research Abstracts Vol. 19, EGU2017-14574-2, 2017 EGU General Assembly 2017 © Author(s) 2017. CC Attribution 3.0 License. Geological mapping of the Kuiper quadrangle (H06) of Mercury Lorenza Giacomini (1), Matteo Massironi (1), and Valentina Galluzzi (2) (1) Dipartimento di Geoscienze, Università degli Studi di Padova, Padua, Italy ([email protected]), (2) INAF, Istituto di Astrofisica e Planetologia Spaziali, Rome, Italy Kuiper quadrangle (H06) is located at the equatorial zone of Mercury and encompasses the area between longitudes 288◦E – 360◦E and latitudes 22.5◦N – 22.5◦S. The quadrangle was previously mapped for its most part by De Hon et al. (1981) that, using Mariner10 data, produced a final 1:5M scale map of the area. In this work we present the preliminary results of a more detailed geological map (1:3M scale) of the Kuiper quadrangle that we compiled using the higher resolution of MESSENGER data. The main basemap used for the mapping is the MDIS (Mercury Dual Imaging System) 166 m/pixel BDR (map-projected Basemap reduced Data Record) mosaic. Additional datasets were also taken into account, such as DLR stereo-DEM of the region (Preusker et al., 2016), global mosaics with high-incidence illumination from the east and west (Chabot et al., 2016) and MDIS global color mosaic (Denevi et al., 2016). The preliminary geological map shows that the western part of the quadrangle is characterized by a prevalence of crater materials (i.e. crater floor, crater ejecta) which were distinguished into three classes on the basis of their degradation degree (Galluzzi et al., 2016).
    [Show full text]
  • Planet Mercury
    Rothery David A. Rothery Planet Mercury David A. Rothery From Pale Pink Dot to Dynamic World A new and detailed picture of Mercury is emerging thanks to NASA’s MESSENGER mission that spent four years in orbit about the Sun’s innermost planet. Comprehen- sively illustrated by close-up images and other data, the author describes Mercury’s landscapes from a geological perspective: from sublimation hollows, to volcanic vents, to lava plains, to giant thrust faults. He considers what its giant core, internal structure and weird composition have to tell us about the formation and evolution of a planet so close to the Sun. This is of special significance in view of the discovery of so many exo- planets in similarly close orbits about their stars. Mercury generates its own magnetic field, like the Earth (but unlike Venus, Mars and the Moon), and the interplay between Mercury’s and the Sun’s magnetic field affects many processes on its surface and in the rich and diverse exosphere of neutral and charged particles surrounding the planet. There is much about Mercury that we still don’t understand. Accessible to the amateur, but also a handy state-of-the-art digest for students and researchers, the book shows how our knowledge of Mercury developed over the past century of ground-based, Planet fly-by and orbital observations, and looks ahead at the mysteries remaining for future 1 missions to explore. Planet Mercury Mercury From Pale Pink Dot to Dynamic World Astronomy / Astrophysics ISBN 978-3-319-12116-1 9 7 8 3 3 1 9 1 2 1 1 6 1 Planet Mercury More information about this series at http://www.springer.com/series/4097 David A.
    [Show full text]