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101. PLANETARY SCIENCE: Low-altitude magnetic field measurements by MESSENGER reveal Mercuryʼs ancient crustal field

Author

Johnson, Catherine L., Phillips, Roger J., Purucker, Michael E., Anderson, Brian J., Byrne, Paul K., Denevi, Brett W., Feinberg, Joshua M., Hauck, Steven A., II, Head, James W., III, Korth, Haje, James, Peter B., Mazarico, Erwan, Neumann, Gregory A., Philpott, Lydia C., Siegler, Matthew A., Tsyganenko, Nikolai A., and Solomon, Sean C.

Published
2015
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105. An Overview of Venus Geology

Author

Saunders, R. Stephen, Arvidson, Raymond E., Head, James W., Schaber, Gerald G., Stofan, Ellen R., and Solomon, Sean C.

Published
1991

109. Structure of the Moon

Author

Toksöz, M. Nafi, primary, Dainty, Anton M., additional, Solomon, Sean C., additional, and Anderson, Kennethr R., additional

Published
2014
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110. The Gravity Field of Mercury After the Messenger Low-Altitude Campaign

Author

Mazarico, Erwan, Genova, Antonio, Goossens, Sander, Lemoine, Frank G, Smith, David E, Zuber, Maria T, Neumann, Gary A, and Solomon, Sean C

Subjects
Geophysics
Abstract

The final year of the MESSENGER mission was designed to take advantage of the remaining propellant onboard to provide a series of lowaltitude observation campaigns and acquire novel scientific data about the innermost planet. The lower periapsis altitude greatly enhances the sensitivity to the short-wavelength gravity field, but only when the spacecraft is in view of Earth. After more than 3 years in orbit around Mercury, the MESSENGER spacecraft was tracked for the first time below 200-km altitude on 5 May 2014 by the NASA Deep Space Network (DSN). Between August and October, periapsis passages down to 25-km altitude were routinely tracked. These periods considerably improved the quality of the data coverage. Before the end of its mission, MESSENGER will fly at very low altitudes for extended periods of time. Given the orbital geometry, however the periapses will not be visible from Earth and so no new tracking data will be available for altitudes lower than ~75 km. Nevertheless, the continuous tracking of MESSENGER in the northern hemisphere will help improve the uniformity of the spatial coverage at altitudes lower than ~150 km, which will further improve the overall quality of the Mercury gravity field.

Published
2015

112. The Magnetic Field of Mercury

Author

Anderson, Brian J., Acuña, Mario H., Korth, Haje, Slavin, James A., Uno, Hideharu, Johnson, Catherine L., Purucker, Michael E., Solomon, Sean C., Raines, Jim M., Zurbuchen, Thomas H., Gloeckler, George, and McNutt, Jr., Ralph L.

Published
2010
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113. The apparent lack of lunar-like swirls on Mercury: Implications for the formation of lunar swirls and for the agent of space weathering

Author

Blewett, David T., Denevi, Brett W., Robinson, Mark S., Ernst, Carolyn M., Purucker, Michael E., and Solomon, Sean C.

Subjects
Outer space -- Discovery and exploration, Magnetic anomalies, Magnetic fields, Astronomy, Earth sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.icarus.2010.03.008 Byline: David T. Blewett (a), Brett W. Denevi (b), Mark S. Robinson (b), Carolyn M. Ernst (a), Michael E. Purucker (c), Sean C. Solomon (d) Keywords: Mercury, Surface; Moon, Surface; Solar wind; Magnetic fields Abstract: Images returned by the MESSENGER spacecraft from the Mercury flybys have been examined to search for anomalous high-albedo markings similar to lunar swirls. Several features suggested to be swirls on the basis of Mariner 10 imaging (in the craters Handel and Lermontov) are seen in higher-resolution MESSENGER images to lack the characteristic morphology of lunar swirls. Although antipodes of large impact basins on the Moon are correlated with swirls, the antipodes of the large impact basins on Mercury appear to lack unusual albedo markings. The antipodes of Mercury's Rembrandt, Beethoven, and Tolstoj basins do not have surface textures similar to the 'hilly and lineated' terrain found at the Caloris antipode, possibly because these three impacts were too small to produce obvious surface disturbances at their antipodes. Mercury does have a class of unusual high-reflectance features, the bright crater-floor deposits (BCFDs). However, the BCFDs are spectral outliers, not simply optically immature material, which implies the presence of material with an unusual composition or physical state. The BCFDs are thus not analogs to the lunar swirls. We suggest that the lack of lunar-type swirls on Mercury supports models for the formation of lunar swirls that invoke interaction between the solar wind and crustal magnetic anomalies (i.e., the solar-wind standoff model and the electrostatic dust-transport model) rather than those models of swirl formation that relate to cometary impact phenomena. If the solar-wind standoff hypothesis for lunar swirls is correct, it implies that the primary agent responsible for the optical effects of space weathering on the Moon is solar-wind ion bombardment rather than micrometeoroid impact. Author Affiliation: (a) Johns Hopkins University, Applied Physics Laboratory, 11100 Johns Hopkins Road, Laurel, MD 20723, USA (b) School of Earth and Space Exploration, Arizona State University, Tempe, AZ 85287, USA (c) Raytheon/NASA Goddard Space Flight Center, Greenbelt, MD 20771, USA (d) Department of Terrestrial Magnetism, Carnegie Institution of Washington, Washington, DC 20015, USA Article History: Received 23 July 2009; Revised 10 March 2010; Accepted 11 March 2010

Published
2010

114. The morphology of Mercury's Caloris basin as seen in MESSENGER stereo topographic models

Author

Oberst, JuRgen, Preusker, Frank, Phillips, Roger J., Watters, Thomas R., Head, James W., Zuber, Maria T., and Solomon, Sean C.

Subjects
Basins (Geology) -- Environmental aspects, Basins (Geology) -- Models, Basins (Geology) -- Analysis, Cratering -- Environmental aspects, Cratering -- Models, Cratering -- Analysis, Museums -- Environmental aspects, Museums -- Models, Museums -- Analysis, Astronomy, Earth sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.icarus.2010.03.009 Byline: Jurgen Oberst (a), Frank Preusker (a), Roger J. Phillips (b), Thomas R. Watters (c), James W. Head (d), Maria T. Zuber (e), Sean C. Solomon (f) Keywords: Mercury; Cratering; Geological processes Abstract: A digital terrain model (1000-m effective spatial resolution) of the Caloris basin, the largest well-characterized impact basin on Mercury, was produced from 208 stereo images obtained by the MESSENGER narrow-angle camera. The basin rim is far from uniform and is characterized by rugged terrain or knobby plains, often disrupted by craters and radial troughs. In some sectors, the rim is represented by a single marked elevation step, where height levels drop from the surroundings toward the basin interior by approximately 2km. Two concentric rings, with radii of 690km and 850km, can be discerned in the topography. Several pre-Caloris basins and craters can be identified from the terrain model, suggesting that rugged pre-impact topography may have contributed to the varying characteristics of the Caloris rim. The basin interior is relatively smooth and shallow, comparable to typical lunar mascon mare basins, supporting the idea that Caloris was partially filled with lava after formation. The model displays long-wavelength undulations in topography across the basin interior, but these undulations cannot readily be related to pre-impact topography, volcanic construction, or post-volcanic uplift. Because errors in the long-wavelength topography of the model cannot be excluded, confirmation of these undulations must await data from MESSENGER's orbital mission phase. Author Affiliation: (a) German Aerospace Center, Institute of Planetary Research, D-12489 Berlin, Germany (b) Planetary Science Directorate, Southwest Research Institute, Boulder, CO 80302, USA (c) Center for Earth and Planetary Studies, National Air and Space Museum, Smithsonian Institution, Washington, DC 20560, USA (d) Department of Geological Sciences, Brown University, Providence, RI 02912, USA (e) Department of Earth, Atmospheric, and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, MA 02139-4307, USA (f) Department of Terrestrial Magnetism, Carnegie Institution of Washington, Washington, DC 20015, USA Article History: Received 30 October 2009; Revised 1 March 2010; Accepted 10 March 2010

Published
2010

115. The scientific rationale for deployment of a long-lived geophysical network on the Moon

Author

Weber, Renee, primary, Neal, Clive R., additional, Grimm, Robert, additional, Grott, Matthias, additional, Schmerr, Nicholas, additional, Wieczorek, Mark, additional, Williams, James, additional, Banerdt, Bruce, additional, Beghein, Caroline, additional, Chi, Peter, additional, Currie, Douglas, additional, Dell'Agnello, Simone, additional, Espley, Jared, additional, Garcia, Raphael, additional, Garrick-Bethell, Ian, additional, Haviland, Heidi, additional, Indyk, Stephen, additional, Johnson, Catherine, additional, Kawamura, Taichi, additional, Kedar, Sharon, additional, Lognonné, Philippe, additional, Nagihara, Seiichi, additional, Nakamura, Yosio, additional, Nunn, Ceri, additional, Ostrach, Lillian R., additional, Panning, Mark, additional, Petro, Noah, additional, Siegler, Matthew, additional, Watters, Thomas, additional, Zacny, Kris, additional, Bailey, S. Hop, additional, Banks, Maria, additional, Barker, Donald, additional, Bernhardt, Hannes, additional, Bickel, Valentin, additional, Cahill, Josh, additional, Clark, Jackie, additional, DellaGiustina, Dani, additional, Dimech, Jesse-Lee, additional, Dombard, Andrew, additional, Elder, Catherine, additional, Elkins-Tanton, Lindy, additional, Eubanks, Marshall, additional, Hanna, Kerri Donaldson, additional, Harms, Jan, additional, Hauck, Steve, additional, Hood, Lon, additional, Jr., José Hurtado,, additional, Jacobson, Seth, additional, Jha, Devanshu, additional, Keane, James Tuttle, additional, Khan, Amir, additional, Kiefer, Walter, additional, Knapmeyer, Martin, additional, Knapmeyer-Endrun, Brigitte, additional, Khurana, Krishan, additional, Lorenzo, Juan, additional, Marusiak, Angela, additional, McGovern, Patrick, additional, Montesi, Laurent, additional, Nimmo, Francis, additional, Phillips, Deanna, additional, Richardson, Jacob, additional, Shearer, Charles, additional, Soderlund, Krista, additional, Solomon, Sean C., additional, Spohn, Tilman, additional, Stutzmann, Eleonore, additional, Tikoo, Sonia, additional, Turyshev, Slava, additional, Waller, Dany, additional, Yamada, Ryuhei, additional, and Zuber, Maria, additional

Published
2021
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116. Missions to Mercury

Author

Balogh, André, Grard, Réjean, Solomon, Sean C., Schulz, Rita, Langevin, Yves, Kasaba, Yasumasa, and Fujimoto, Masaki

Published
2007
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117. Thalassa: A Mission to Follow the Water on Venus

Author

Byrne, Paul, Frank, Elizabeth, Dyar, Melinda, Helbert, Jörn, Illsley, Peter, Komjathy, Attila, Krishnamoorthy, Siddharth, Lillis, Robert J., O'Rourke, Joseph, Royer, Emilie, Solomon, Sean C., Tsang, C. C. C., Voorhees, Christopher, and Wilson, Colin

Subjects
Planetare Labore, Spektroskopie, Atmosphäre, Venus
Published
2020

118. Mercury's Surface Magnetic Field Determined from Proton-Reflection Magnetometry

Author

Winslow, Reka M, Johnson, Catherine L, Anderson, Brian J, Gershman, Daniel J, Raines, Jim M, Lillis, Robert J, Korth, Haje, Slavin, James A, Solomon, Sean C, Zurbuchen, Thomas H, and Zuber, Maria T

Subjects
Solar Physics, Lunar And Planetary Science And Exploration, Plasma Physics
Abstract

Solar wind protons observed by the MESSENGER spacecraft in orbit about Mercury exhibit signatures of precipitation loss to Mercury's surface. We apply proton-reflection magnetometry to sense Mercury's surface magnetic field intensity in the planet's northern and southern hemispheres. The results are consistent with a dipole field offset to the north and show that the technique may be used to resolve regional-scale fields at the surface. The proton loss cones indicate persistent ion precipitation to the surface in the northern magnetospheric cusp region and in the southern hemisphere at low nightside latitudes. The latter observation implies that most of the surface in Mercury's southern hemisphere is continuously bombarded by plasma, in contrast with the premise that the global magnetic field largely protects the planetary surface from the solar wind.

Published
2014
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119. Structure and Evolution of the Lunar Procellarum Region as Revealed by GRAIL Gravity Data

Author

Andrews-Hanna, Jeffrey C, Besserer, Jonathan, Head, James W., III, Howett, Carly J. A, Kiefer, Walter S, Lucey, Paul J, McGovern, Patrick J, Melosh, H. Jay, Neumann, Gregory A, Phillips, Roger J, Schenk, Paul M, Smith, David E, Solomon, Sean C, and Zuber, Maria T

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Procellarum region is a broad area on the nearside of the Moon that is characterized by low elevations, thin crust, and high surface concentrations of the heat-producing elements uranium, thorium, and potassium. The Procellarum region has been interpreted as an ancient impact basin approximately 3200 km in diameter, though supporting evidence at the surface would have been largely obscured as a result of the great antiquity and poor preservation of any diagnostic features. Here we use data from the Gravity Recovery and Interior Laboratory (GRAIL) mission to examine the subsurface structure of Procellarum. The Bouguer gravity anomalies and gravity gradients reveal a pattern of narrow linear anomalies that border the Procellarum region and are interpreted to be the frozen remnants of lava-filled rifts and the underlying feeder dikes that served as the magma plumbing system for much of the nearside mare volcanism. The discontinuous surface structures that were earlier interpreted as remnants of an impact basin rim are shown in GRAIL data to be a part of this continuous set of quasi-rectangular border structures with angular intersections, contrary to the expected circular or elliptical shape of an impact basin. The spatial pattern of magmatic-tectonic structures bounding Procellarum is consistent with their formation in response to thermal stresses produced by the differential cooling of the province relative to its surroundings, coupled with magmatic activity driven by the elevated heat flux in the region.

Published
2014
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120. Plasma Distribution in Mercury's Magnetosphere Derived from MESSENGER Magnetometer and Fast Imaging Plasma Spectrometer Observations

Author

Korth, Haje, Anderson, Brian J, Gershman, Daniel J, Raines, Jim M, Slavin, James A, Zurbuchen, Thomas H, Solomon, Sean C, and McNutt, Ralph L

Subjects
Plasma Physics
Abstract

We assess the statistical spatial distribution of plasma in Mercury's magnetosphere from observations of magnetic pressure deficits and plasma characteristics by the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft. The statistical distributions of proton flux and pressure were derived from 10months of Fast Imaging Plasma Spectrometer (FIPS) observations obtained during the orbital phase of the MESSENGER mission. The Magnetometer-derived pressure distributions compare favorably with those deduced from the FIPS observations at locations where depressions in the magnetic field associated with the presence of enhanced plasma pressures are discernible in the Magnetometer data. The magnitudes of the magnetic pressure deficit and the plasma pressure agree on average, although the two measures of plasma pressure may deviate for individual events by as much as a factor of approximately 3. The FIPS distributions provide better statistics in regions where the plasma is more tenuous and reveal an enhanced plasma population near the magnetopause flanks resulting from direct entry of magnetosheath plasma into the low-latitude boundary layer of the magnetosphere. The plasma observations also exhibit a pronounced north-south asymmetry on the nightside, with markedly lower fluxes at low altitudes in the northern hemisphere than at higher altitudes in the south on the same field line. This asymmetry is consistent with particle loss to the southern hemisphere surface during bounce motion in Mercury's offset dipole magnetic field.

Published
2014
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121. Global Inventory and Characterization of Pyroclastic Deposits on Mercury: New Insights into Pyroclastic Activity from MESSENGER Orbital Data

Author

Goudge, Timothy A, Head, James W, Kerber, Laura, Blewett, David T, Denevi, Brett W, Domingue, Deborah L, Gillis-Davis, Jeffrey J, Gwinner, Klaus, Helbert, Joern, Holsclaw, Gregory M, Izenberg, Noam R, Klima, Rachel L, McClintock, William E, Murchie, Scott L, Neumann, Gregory A, Smith, David E, Strom, Robert G, Xiao, Zhiyong, Zuber, Maria T, and Solomon, Sean C

Subjects
Lunar And Planetary Science And Exploration
Abstract

We present new observations of pyroclastic deposits on the surface of Mercury from data acquired during the orbital phase of the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) mission. The global analysis of pyroclastic deposits brings the total number of such identified features from 40 to 51. Some 90% of pyroclastic deposits are found within impact craters. The locations of most pyroclastic deposits appear to be unrelated to regional smooth plains deposits, except some deposits cluster around the margins of smooth plains, similar to the relation between many lunar pyroclastic deposits and lunar maria. A survey of the degradation state of the impact craters that host pyroclastic deposits suggests that pyroclastic activity occurred on Mercury over a prolonged interval. Measurements of surface reflectance by MESSENGER indicate that the pyroclastic deposits are spectrally distinct from their surrounding terrain, with higher reflectance values, redder (i.e., steeper) spectral slopes, and a downturn at wavelengths shorter than approximately 400nm (i.e., in the near-ultraviolet region of the spectrum). Three possible causes for these distinctive characteristics include differences in transition metal content, physical properties (e.g., grain size), or degree of space weathering from average surface material on Mercury. The strength of the near-ultraviolet downturn varies among spectra of pyroclastic deposits and is correlated with reflectance at visible wavelengths. We suggest that this interdeposit variability in reflectance spectra is the result of either variable amounts of mixing of the pyroclastic deposits with underlying material or inherent differences in chemical and physical properties among pyroclastic deposits.

Published
2014
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122. Asymmetric Distribution of Lunar Impact Basins Caused by Variations in Target Properties

Author

Miljkovic, Katarina, Wieczorek, Mark A, Collins, Gareth S, Laneuville, Matthieu, Neumann, Gregory A, Melosh, H. Jay, Solomon, Sean C, Phillips, Roger J, Smith, David E, and Zuber, Maria T

Subjects
Lunar And Planetary Science And Exploration
Abstract

Maps of crustal thickness derived from NASA's Gravity Recovery and Interior Laboratory (GRAIL) mission revealed more large impact basins on the nearside hemisphere of the Moon than on its farside. The enrichment in heat-producing elements and prolonged volcanic activity on the lunar nearside hemisphere indicate that the temperature of the nearside crust and upper mantle was hotter than that of the farside at the time of basin formation. Using the iSALE-2D hydrocode to model impact basin formation, we found that impacts on the hotter nearside would have formed basins up to two times larger than similar impacts on the cooler farside hemisphere. The size distribution of lunar impact basins is thus not representative of the earliest inner Solar system impact bombardment.

Published
2014

123. The Gravity Field, Orientation, and Ephemeris of Mercury from MESSENGER Observations After Three Years in Orbit

Author

Mazarico, Erwan M, Genova, Antonio, Goossens, Sander, Lemoine, Gregory, Neumann, Gregory A, Zuber, Maria T, Smith, David E, and Solomon, Sean C

Subjects
Lunar And Planetary Science And Exploration
Abstract

We have analyzed three years of radio tracking data from the MESSENGER spacecraft in orbit around Mercury and determined the gravity field, planetary orientation, and ephemeris of the innermost planet. With improvements in spatial coverage, force modeling, and data weighting, we refined an earlier global gravity field both in quality and resolution, and we present here a spherical harmonic solution to degree and order 50. In this field, termed HgM005, uncertainties in low-degree coefficients are reduced by an order of magnitude relative to the earlier global field, and we obtained a preliminary value of the tidal Love number k(sub 2) of 0.451+/-0.014. We also estimated Mercury's pole position, and we obtained an obliquity value of 2.06 +/- 0.16 arcmin, in good agreement with analysis of Earth-based radar observations. From our updated rotation period (58.646146 +/- 0.000011 days) and Mercury ephemeris, we verified experimentally the planet's 3: 2 spin-orbit resonance to greater accuracy than previously possible. We present a detailed analysis of the HgM005 covariance matrix, and we describe some near-circular frozen orbits around Mercury that could be advantageous for future exploration.

Published
2014
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124. Supplemental Information For: Asymmetric Distribution of Lunar Impact Basins Caused by Variations in Target Properties

Author

Miljkovic, Katarina, Wieczorek, Mark, Collins, Gareth S, Laneuville, Matthieu, Neumann, Gregory A, Melosh, H. Jay, Solomon, Sean C, Phillips, Roger J, Smith, David E, and Zuber, Maria T

Subjects
Lunar And Planetary Science And Exploration
Abstract

Maps of crustal thickness derived from NASA's Gravity Recovery and Interior Laboratory (GRAIL) mission revealed more large impact basins on the nearside hemisphere of the Moon than on its farside. The enrichment in heat-producing elements and prolonged volcanic activity on the lunar nearside hemisphere indicate that the temperature of the nearside crust and uppermantle was hotter than that of the farside at the time of basin formation. Using the iSALE-2D hydrocode to model impact basin formation, we found that impacts on the hotter nearside would have formed basins up to two times larger than similar impacts on the cooler farside hemisphere. The size distribution of lunar impact basins is thus not representative of the earliest inner Solar system impact bombardment

Published
2014

126. The Magnetic Field of Mercury

Author

Anderson, Brian J., primary, Acuña, Mario H., additional, Korth, Haje, additional, Slavin, James A., additional, Uno, Hideharu, additional, Johnson, Catherine L., additional, Purucker, Michael E., additional, Solomon, Sean C., additional, Raines, Jim M., additional, Zurbuchen, Thomas H., additional, Gloeckler, George, additional, and McNutt, Ralph L., additional

Published
2009
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127. MESSENGER at Mercury: Early Orbital Operations

Author

McNutt, Ralph L., Jr, Solomon, Sean C, Bedini, Peter D, Anderson, Brian J, Blewett, David T, Evans, Larry G, Gold, Robert E, Krimigis, Stamatios M, Murchie, Scott L, Nittler, Larry R, Philips, Roger J, Prockter, Louise M, Slavin, James A, Zuber, M. T, Finnegan, Eric J, and Grant, David G

Subjects
Lunar And Planetary Science And Exploration
Abstract

The MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft, launched in August 2004 under NASA's Discovery Program, was inserted into orbit about the planet Mercury in March 2011. MESSENGER's three flybys of Mercury in 2008-2009 marked the first spacecraft visits to the innermost planet since the Mariner 10 flybys in 1974-1975. The unprecedented orbital operations are yielding new insights into the nature and evolution of Mercury. The scientific questions that frame the MESSENGER mission led to the mission measurement objectives to be achieved by the seven payload instruments and the radio science experiment. Interweaving the full set of required orbital observations in a manner that maximizes the opportunity to satisfy all mission objectives and yet meet stringent spacecraft pointing and thermal constraints was a complex optimization problem that was solved with a software tool that simulates science observations and tracks progress toward meeting each objective. The final orbital observation plan, the outcome of that optimization process, meets all mission objectives. MESSENGER's Mercury Dual Imaging System is acquiring a global monochromatic image mosaic at better than 90% coverage and at least 250 m average resolution, a global color image mosaic at better than 90% coverage and at least 1 km average resolution, and global stereo imaging at better than 80% coverage and at least 250 m average resolution. Higher-resolution images are also being acquired of targeted areas. The elemental remote sensing instruments, including the Gamma-Ray and Neutron Spectrometer and the X-Ray Spectrometer, are being operated nearly continuously and will establish the average surface abundances of most major elements. The Visible and Infrared Spectrograph channel of MESSENGER's Mercury Atmospheric and Surface Composition Spectrometer is acquiring a global map of spectral reflectance from 300 to 1450 nm wavelength at a range of incidence and emission angles. Targeted areas have been selected for spectral coverage into the ultraviolet with the Ultraviolet and Visible Spectrometer (UVVS). MESSENGER's Mercury Laser Altimeter is acquiring topographic profiles when the slant range to Mercury's surface is less than 1800 km, encompassing latitudes from 20 deg. S to the north pole. Topography over the remainder of the southern hemisphere will be derived from stereo imaging, radio occultations, and limb profiles. MESSENGER's radio science experiment is determining Mercury's gravity field from Doppler signals acquired during frequent downlinks. MESSENGER's Magnetometer is measuring the vector magnetic field both within Mercury's magnetosphere and in Mercury's solar wind environment at an instrument sampling rate of up to 20 samples/s. The UVVS is determining the three-dimensional, time-dependent distribution of Mercury's exospheric neutral and ionic species via their emission lines. During each spacecraft orbit, the Energetic Particle Spectrometer measures energetic electrons and ions, and the Fast Imaging Plasma Spectrometer measures the energies and mass per charge of thermal plasma components, both within Mercury's magnetosphere and in Mercury's solar-wind environment. The primary mission observation sequence will continue for one Earth year, until March 2012. An extended mission, currently under discussion with NASA, would add a second year of orbital observations targeting a set of focused follow-on questions that build on observations to date and take advantage of the more active Sun expected during 2012-2013. MESSENGER's total primary mission cost, projected at $446 M in real-year dollars, is comparable to that of Mariner 10 after adjustment for inflation.

Published
2013
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128. Properties of the Lunar Interior: Preliminary Results from the GRAIL Mission

Author

Williams, James G, Konopliv, Alexander S, Asmar, Sami W, Lemoine, Frank G, Melosh, H. Jay, Neumann, Gregory A, Phillips, Roger J, Smith, David E, Solomon, Sean C, Watkins, Michael M, Wieczorek, Mark A, Zuber, Maria T, Andrews-Hanna, Jeffrey C, Head, James W, Kiefer, Walter S, McGovern, Patrick J, Nimmo, Francis, Taylor, G. Jeffrey, Weber, Renee C, Boggs, D. H, Goossens, Sander J, Kruizinga, Gerhard L, Mazarico, Erwan, Park, Ryan S, and Yuan, Dah-Ning

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Gravity Recovery and Interior Laboratory (GRAIL) mission [1] has provided lunar gravity with unprecedented accuracy and resolution. GRAIL has produced a high-resolution map of the lunar gravity field [2,3] while also determining tidal response. We present the latest gravity field solution and its preliminary implications for the Moon's interior structure, exploring properties such as the mean density, moment of inertia of the solid Moon, and tidal potential Love number k(sub 2). Lunar structure includes a thin crust, a thick mantle layer, a fluid outer core, and a suspected solid inner core. An accurate Love number mainly improves knowledge of the fluid core and deep mantle. In the future, we will search for evidence of tidal dissipation and a solid inner core using GRAIL data.

Published
2013

129. Gravity Recovery and Interior Laboratory (GRAIL): Extended Mission and End-Game Status

Author

Zuber, Maria T, Smith, David E, Wieczorek, Mark A, Williams, James G, Andrews-Hanna, Jeffrey C, Head, James W, Kiefer, Walter S, Matsuyama, Isamu, McGovern, Patrick J, Nimmo, Francis, Stubbs, Christopher, Weber, Renee, Asmar, Sami W, Goossens, Sander J, Kruizinga, Gerhard, Mazarico, Erwan, Park, Ryan S, Yuan, Dah-Ning, Konopliv, Alexander S, Lemoine, Frank G, Melosh, H. Jay, Neumann, Gregory A, Phillips, Roger J, Solomon, Sean C, and Watkins, Michael M

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Gravity Recovery and Interior Laboratory (GRAIL) [1], NASA s eleventh Discovery mission, successfully executed its Primary Mission (PM) in lunar orbit between March 1, 2012 and May 29, 2012. GRAIL s Extended Mission (XM) initiated on August 30, 2012 and was successfully completed on December 14, 2012. The XM provided an additional three months of gravity mapping at half the altitude (23 km) of the PM (55 km), and is providing higherresolution gravity models that are being used to map the upper crust of the Moon in unprecedented detail.

Published
2013

130. Preliminary Results on Lunar Interior Properties from the GRAIL Mission

Author

Williams, James G, Konopliv, Alexander S, Asmar, Sami W, Lemoine, H. Jay, Melosh, H. Jay, Neumann, Gregory A, Phillips, Roger J, Smith, David E, Solomon, Sean C, Watkins, Michael M, Wieczorek, Mark A, Zuber, Maria T, Andrews-Hanna, Jeffrey C, Head, James W, Kiefer, Walter S, Matsuyama, Isamu, McGovern, Patrick J, Nimmo, Francis, Weber, Renee C, Boggs, D. H, Goossens, Sander J, Kruizinga, Gerhard L, Mazarico, Erwan, Park, Ryan S, and Yuan, Dah-Ning

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Gravity Recovery and Interior Laboratory (GRAIL) mission has provided lunar gravity with unprecedented accuracy and resolution. GRAIL has produced a high-resolution map of the lunar gravity field while also determining tidal response. We present the latest gravity field solution and its preliminary implications for the Moon's interior structure, exploring properties such as the mean density, moment of inertia of the solid Moon, and tidal potential Love number k2. Lunar structure includes a thin crust, a deep mantle, a fluid core, and a suspected solid inner core. An accurate Love number mainly improves knowledge of the fluid core and deep mantle. In the future GRAIL will search for evidence of tidal dissipation and a solid inner core.

Published
2013

131. Revised Thickness of the Lunar Crust from GRAIL Data: Implications for Lunar Bulk Composition

Author

Taylor, G. Jeffrey, Wieczorek, Mark A, Neumann, Gregory A, Nimmo, Francis, Kiefer, Walter S, Melosh, H. Jay, Phillips, Roger J, Solomon, Sean C, Andrews-Hanna, Jeffrey C, Asmar, Sami W, Konopliv, Alexander S, Lemoine, Frank G, Smith, David E, Watkins, Michael W, Williams, James G, and Zuber, Maria T

Subjects
Lunar And Planetary Science And Exploration
Abstract

High-resolution gravity data from GRAIL have yielded new estimates of the bulk density and thickness of the lunar crust. The bulk density of the highlands crust is 2550 kg m-3. From a comparison with crustal composition measured remotely, this density implies a mean porosity of 12%. With this bulk density and constraints from the Apollo seismic experiment, the average global crustal thickness is found to lie between 34 and 43 km, a value 10 to 20 km less than several previous estimates. Crustal thickness is a central parameter in estimating bulk lunar composition. Estimates of the concentrations of refractory elements in the Moon from heat flow, remote sensing and sample data, and geophysical data fall into two categories: those with refractory element abundances enriched by 50% or more relative to Earth, and those with abundances the same as Earth. Settling this issue has implications for processes operating during lunar formation. The crustal thickness resulting from analysis of GRAIL data is less than several previous estimates. We show here that a refractory-enriched Moon is not required

Published
2013

132. Missions to Mercury

Author

Balogh, André, primary, Grard, Réjean, additional, Solomon, Sean C., additional, Schulz, Rita, additional, Langevin, Yves, additional, Kasaba, Yasumasa, additional, and Fujimoto, Masaki, additional

Published
2008
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133. Mercury's Sodium Exosphere: Observations during the MESSENGER Orbital Phase

Author

Killen, Rosemary M, Cassidy, Timothy A, Vervack, Ronald J., Jr, Burger, Matthew H, Merkel, Aimee W, Sarantos, Menelaos, Sprague, Ann L, McClintock, William E, Benna, Mehdi, and Solomon, Sean C

Subjects
Space Sciences (General)
Abstract

The MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft entered into orbit about Mercury on March 18,2011. We now have approximately five Mercury years of data from orbit. Prior to the MESSENGER mission, Mercury's surface-bounded exosphere was known to contain H, He, Na. K, and Ca. The Ultraviolet and Visible Spectrometer (UVVS) began routine orbital observations of both the dayside and nightside exosphere on March 29. 2011, measuring altitude profiles for all previously detected neutral species except for He and K. We focus here on what we have learned about the sodium exosphere: its spatial, seasonal, and sporadic variation. Observations to date permit delineation of the relative roles of photon-stimulated desorption (PSD) and impact vaporization (IV) from seasonal and spatial effects, as well as of the roles of ions both as sputtering agents and in their possible role to enhance the efficiency of PSD. Correlations of Mercury's neutral sodium exosphere with measurements from MESSENGER's Magnetometer (MAG) and Energetic Particle and Plasma Spectrometer (EPPS) provide insight into the roles of ions and electrons. Models incorporating MAG observations provide a basis for identifying the location and area of the surface exposed to solar wind plasma, and EPPS observations reveal episodic populations of energetic electrons in the magnetosphere and the presence of planetary He(+), 0(+), and Na(+)

Published
2012

134. Low-degree Structure in Mercury's Planetary Magnetic Field

Author

Anderson, Brian J, Johnson, Catherine L, Korth, Haje, Winslow, Reka M, Borovsky, Joseph E, Purucker, Michael E, Slavin, James A, Solomon, Sean C, Zuber, Maria T, and McNutt, Ralph L. Jr

Subjects
Lunar And Planetary Science And Exploration
Abstract

The structure of Mercury's internal magnetic field has been determined from analysis of orbital Magnetometer measurements by the MESSENGER spacecraft. We identified the magnetic equator on 531 low-altitude and 120 high-altitude equator crossings from the zero in the radial cylindrical magnetic field component, Beta (sub rho). The low-altitude crossings are offset 479 +/- 6 km northward, indicating an offset of the planetary dipole. The tilt of the magnetic pole relative to the planetary spin axis is less than 0.8 deg.. The high-altitude crossings yield a northward offset of the magnetic equator of 486 +/- 74 km. A field with only nonzero dipole and octupole coefficients also matches the low-altitude observations but cannot yield off-equatorial Beta (sub rho) = 0 at radial distances greater than 3520 km. We compared offset dipole and other descriptions of the field with vector field observations below 600 km for 13 longitudinally distributed, magnetically quiet orbits. An offset dipole with southward directed moment of 190 nT-R-cube (sub M) yields root-mean-square (RMS) residuals below 14 nT, whereas a field with only dipole and octupole terms tuned to match the polar field and the low-altitude magnetic equator crossings yields RMS residuals up to 68 nT. Attributing the residuals from the offset-dipole field to axial degree 3 and 4 contributions we estimate that the Gauss coefficient magnitudes for the additional terms are less than 4% and 7%, respectively, relative to the dipole. The axial alignment and prominent quadrupole are consistent with a non-convecting layer above a deep dynamo in Mercury's fluid outer core.

Published
2012
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135. Venus tesserae feature layered, folded, and eroded rocks

Author

Byrne, Paul K., primary, Ghail, Richard C., additional, Gilmore, Martha S., additional, Şengör, A.M. Celâl, additional, Klimczak, Christian, additional, Senske, David A., additional, Whitten, Jennifer L., additional, Khawja, Sara, additional, Ernst, Richard E., additional, and Solomon, Sean C., additional

Published
2020
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137. MESSENGER at Mercury: Early Orbital Operations

Author

McNutt, Ralph L., Jr, Solomon, Sean C, Bedini, Peter D, Anderson, Brian J, Blewett, David T, Evans, Larry G, Gold, Robert E, Krimigis, Stamatios M, Murchie, Scott L, Nittler, Larry R, and Slavin, James A

Subjects
Lunar And Planetary Science And Exploration
Abstract

The MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft, launched in August 2004 under NASA's Discovery Program, was inserted into orbit about the planet Mercury in March 2011. MESSENGER's three flybys of Mercury in 2008-2009 marked the first spacecraft visits to the innermost planet since the Mariner 10 flybys in 1974-1975. The unprecedented orbital operations are yielding new insights into the nature and evolution of Mercury. The scientific questions that frame the MESSENGER mission led to the mission measurement objectives to be achieved by the seven payload instruments and the radio science experiment. Interweaving the full set of required orbital observations in a manner that maximizes the opportunity to satisfy all mission objectives and yet meet stringent spacecraft pointing and thermal constraints was a complex optimization problem that was solved with a software tool that simulates science observations and tracks progress toward meeting each objective. The final orbital observation plan, the outcome of that optimization process, meets all mission objectives. MESSENGER's Mercury Dual Imaging System is acquiring a global monochromatic image mosaic at better than 90%coverage and at least 250 m average resolution, a global color image mosaic at better than 90%coverage and at least 1 km average resolution, and global stereo imaging at better than 80%coverage and at least 250 m average resolution. Higher-resolution images are also being acquired of targeted areas. The elemental remote sensing instruments, including the Gamma-Ray and Neutron Spectrometer and the X-Ray Spectrometer, are being operated nearly continuously and will establish the average surface abundances of most major elements. The Visible and Infrared Spectrograph channel of MESSENGER's Mercury Atmospheric and Surface Composition Spectrometer is acquiring a global map of spectral reflectance from 300 to 1450 nm wavelength at a range of incidence and emission angles. Targeted areas have been selected for spectral coverage into the ultraviolet with the Ultraviolet and Visible Spectrometer (UVVS). MESSENGER's Mercury Laser Altimeter is acquiring topographic profiles when the slant range to Mercury's surface is less than 1800 km, encompassing latitudes from 201S to the north pole. Topography over the remainder of the southern hemisphere will be derived from stereo imaging, radio occultations, and limb profiles. MESSENGER's radio science experiment is determining Mercury's gravity field from Doppler signals acquired during frequent downlinks. MESSENGER's Magnetometer is measuring the vector magnetic field both within Mercury's magnetosphere and in Mercury's solar wind environment at an instrument sampling rate of up to 20 samples/s. The UVVS is determining the three-dimensional, time-dependent distribution of Mercury's exospheric neutral and ionic species via their emission lines. During each spacecraft orbit, the Energetic Particle Spectrometer measures energetic electrons and ions, and the Fast Imaging Plasma Spectrometer measures the energies and mass per charge of thermal plasma components, both within Mercury's magnetosphere and in Mercury's solar-wind environment. The primary mission observation sequence will continue for one Earth year, until March 2012. An extended mission, currently under discussion with NASA, would add a second year of orbital observations targeting a set of focused follow-on questions that build on observations to date and take advantage of the more active Sun expected during 2012-2013. MESSENGER's total primary mission cost, projected at $446 M in real-year dollars, is comparable to that of Mariner 10 after adjustment for inflation.

Published
2012
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138. Characterization of the Morphometry of Impact Craters Hosting Polar Deposits in Mercury's North Polar Region

Author

Talpe Matthieu, Zuber, Maria T, Yang, Di, Neumann, Gregory A, Solomon, Sean C, Mazarico, Erwan, and Vilas, Faith

Subjects
Astronomy
Abstract

Earth-based radar images of Mercury show radar-bright material inside impact craters near the planet s poles. A previous study indicated that the polar-deposit-hosting craters (PDCs) at Mercury s north pole are shallower than craters that lack such deposits. We use data acquired by the Mercury Laser Altimeter on the MESSENGER spacecraft during 11 months of orbital observations to revisit the depths of craters at high northern latitudes on Mercury. We measured the depth and diameter of 537 craters located poleward of 45 N, evaluated the slopes of the northern and southern walls of 30 PDCs, and assessed the floor roughness of 94 craters, including nine PDCs. We find that the PDCs appear to have a fresher crater morphology than the non-PDCs and that the radar-bright material has no detectable influence on crater depths, wall slopes, or floor roughness. The statistical similarity of crater depth-diameter relations for the PDC and non-PDC populations places an upper limit on the thickness of the radar-bright material (< 170 m for a crater 11 km in diameter) that can be refined by future detailed analysis. Results of the current study are consistent with the view that the radar-bright material constitutes a relatively thin layer emplaced preferentially in comparatively young craters.

Published
2012
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139. Chemical Heterogeneity on Mercury's Surface Revealed by the MESSENGER X-ray Spectrometer

Author

Weider, Shoshana Z, Nittler, Larry R, Starr, Richard D, McCoy, Timothy J, Stockstill-Cahill, Karen R, Byrne, Paul K, Denevi, Brett W, Head, James W, and Solomon, Sean C

Subjects
Geophysics, Lunar And Planetary Science And Exploration
Abstract

We present the analysis of 205 spatially resolved measurements of the surfacecomposition of Mercury from MESSENGERs X-Ray Spectrometer. The surfacefootprints of these measurements are categorized according to geological terrain. Northernsmooth plains deposits and the plains interior to the Caloris basin differ compositionallyfrom older terrain on Mercury. The older terrain generally has higher MgSi, SSi, andCaSi ratios, and a lower AlSi ratio than the smooth plains. Mercurys surface mineralogyis likely dominated by high-Mg mafic minerals (e.g., enstatite), plagioclase feldspar, andlesser amounts of Ca, Mg, andor Fe sulfides (e.g., oldhamite). The compositionaldifference between the volcanic smooth plains and the older terrain reflects differentabundances of these minerals and points to the crystallization of the smooth plains from amore chemically evolved magma source. High-degree partial melts of enstatite chondritematerial provide a generally good compositional and mineralogical match for much ofthe surface of Mercury. An exception is Fe, for which the low surface abundance onMercury is still higher than that of melts from enstatite chondrites and may indicate anexogenous contribution from meteoroid impacts.

Published
2012
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140. Survey of Coherent Approximately 1 Hz Waves in Mercury's Inner Magnetosphere from MESSENGER Observations

Author

Boardsen, Scott A, Slavin, James A, Anderson, Brian J, Korth, Haje, Schriver, David, and Solomon, Sean C

Subjects
Lunar And Planetary Science And Exploration, Astronomy
Abstract

We summarize observations by the MESSENGER spacecraft of highly coherent waves at frequencies between 0.4 and 5 Hz in Mercury's inner magnetosphere. This survey covers the time period from 24 March to 25 September 2011, or 2.1 Mercury years. These waves typically exhibit banded harmonic structure that drifts in frequency as the spacecraft traverses the magnetic equator. The waves are seen at all magnetic local times, but their observed rate of occurrence is much less on the dayside, at least in part the result of MESSENGER's orbit. On the nightside, on average, wave power is maximum near the equator and decreases with increasing magnetic latitude, consistent with an equatorial source. When the spacecraft traverses the plasma sheet during its equatorial crossings, wave power is a factor of 2 larger than for equatorial crossings that do not cross the plasma sheet. The waves are highly transverse at large magnetic latitudes but are more compressional near the equator. However, at the equator the transverse component of these waves increases relative to the compressional component as the degree of polarization decreases. Also, there is a substantial minority of events that are transverse at all magnetic latitudes, including the equator. A few of these latter events could be interpreted as ion cyclotron waves. In general, the waves tend to be strongly linear and characterized by values of the ellipticity less than 0.3 and wave-normal angles peaked near 90 deg. Their maxima in wave power at the equator coupled with their narrow-band character suggests that these waves might be generated locally in loss cone plasma characterized by high values of the ratio beta of plasma pressure to magnetic pressure. Presumably both electromagnetic ion cyclotron waves and electromagnetic ion Bernstein waves can be generated by ion loss cone distributions. If proton beta decreases with increasing magnetic latitude along a field line, then electromagnetic ion Bernstein waves are predicted to transition from compressional to transverse, a pattern consistent with our observations. We hypothesize that these local instabilities can lead to enhanced ion precipitation and directly feed field-line resonances.

Published
2012
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141. Gravity, Topography, and Magnetic Field of Mercury from Messenger

Author

Neumann, Gregory A, Solomon, Sean C, Zuber, Maria T, Phillips, Roger J, Barnouin, Olivier, Ernst, Carolyn, Goosens, Sander, Hauck, Steven A., II, Head, James W., III, Johnson, Catherine L, Lemoine, Frank G, Margot, Jean-Luc, McNutt, Ralph, Mazarico, Erwan M, Oberst, Jurgen, Peale, Stanley J, Perry, Mark, Purucker, Michael E, Rowlands, David D, and Torrence, Mark H

Subjects
Lunar And Planetary Science And Exploration
Abstract

On 18 March 2011, the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft was inserted into a 12-hour, near-polar orbit around Mercury, with an initial periapsis altitude of 200 km, initial periapse latitude of 60 deg N, and apoapsis at approximately 15,200 km altitude in the southern hemisphere. This orbit has permitted the mapping of regional gravitational structure in the northern hemisphere, and laser altimetry from the MESSENGER spacecraft has yielded a geodetically controlled elevation model for the same hemisphere. The shape of a planet combined with gravity provides fundamental information regarding its internal structure and geologic and thermal evolution. Elevations in the northern hemisphere exhibit a unimodal distribution with a dynamic range of 9.63 km, less than that of the Moon (19.9 km), but consistent with Mercury's higher surface gravitational acceleration. After one Earth-year in orbit, refined models of gravity and topography have revealed several large positive gravity anomalies that coincide with major impact basins. These candidate mascons have anomalies that exceed 100 mGal and indicate substantial crustal thinning and superisostatic uplift of underlying mantle. An additional uncompensated 1000-km-diameter gravity and topographic high at 68 deg N, 33 deg E lies within Mercury's northern volcanic plains. Mercury's northern hemisphere crust is generally thicker at low latitudes than in the polar region. The low-degree gravity field, combined with planetary spin parameters, yields the moment of inertia C/MR2 = 0.353 +/- 0.017, where M=3.30 x 10(exp 23) kg and R=2440 km are Mercury's mass and radius, and a ratio of the moment of inertia of Mercury's solid outer shell to that of the planet of Cm/C = 0.452 +/- 0.035. One proposed model for Mercury's radial density distribution consistent with these results includes silicate crust and mantle layers overlying a dense solid (possibly Fe-S) layer, a liquid Fe-rich outer core of radius 2030 +/- 37 km, and an assumed solid inner core. Magnetic field measurements indicate a northward offset of Mercury's axial magnetic dipole from the geographic equator by 479 +/-3 km and provide evidence for a regional-scale magnetic field approximately collocated with the northern volcanic plains of possible crustal origin. These results from MESSENGER indicate a complex and asymmetric evolution of internal structure and dynamics in this end-member inner planet.

Published
2012

142. Distribution, Statistics, and Resurfacing of Large Impact Basins on Mercury

Author

Fassett, Caleb I, Head, James W, Baker, David M. H, Chapman, Clark R, Murchie, Scott L, Neumann, Gregory A, Oberst, Juergen, Prockter, Louise M, Smith, David E, Solomon, Sean C, Strom, Robert G, Xiao, Zhiyong, and Zuber, Maria T

Subjects
Lunar And Planetary Science And Exploration
Abstract

The distribution and geological history of large impact basins (diameter D greater than or equal to 300 km) on Mercury is important to understanding the planet's stratigraphy and surface evolution. It is also informative to compare the density of impact basins on Mercury with that of the Moon to understand similarities and differences in their impact crater and basin populations [1, 2]. A variety of impact basins were proposed on the basis of geological mapping with Mariner 10 data [e.g. 3]. This basin population can now be re-assessed and extended to the full planet, using data from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft. Note that small-to- medium-sized peak-ring basins on Mercury are being examined separately [4, 5]; only the three largest peak-ring basins on Mercury overlap with the size range we consider here. In this study, we (1) re-examine the large basins suggested on the basis of Mariner 10 data, (2) suggest additional basins from MESSENGER's global coverage of Mercury, (3) assess the size-frequency distribution of mercurian basins on the basis of these global observations and compare it to the Moon, and (4) analyze the implications of these observations for the modification history of basins on Mercury.

Published
2012

143. Dark Material at the Surface of Polar Crater Deposits on Mercury

Author

Neumann, Gregory A, Cavanaugh, John F, Sun, Xiaoli, Mazarico, Erwan, Smith, David E, Zuber, Maria T, Solomon, Sean C, and Paige, Daid A

Subjects
Lunar And Planetary Science And Exploration
Abstract

Earth-based radar measurements [1-3] have yielded images of radar-bright material at the poles of Mercury postulated to be near-surface water ice residing in cold traps on the permanently shadowed floors of polar impact craters. The Mercury Laser Altimeter (MLA) on board the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft has now mapped much of the north polar region of Mercury [4] (Fig. 1). Radar-bright zones lie within polar craters or along poleward-facing scarps lying mainly in shadow. Calculations of illumination with respect to solid-body motion [5] show that at least 0.5% of the surface area north of 75deg N lies in permanent shadow, and that most such permanently shadowed regions (PSRs) coincide with radar-bright regions. MLA transmits a 1064-nm-wavelength laser pulse at 8 Hz, timing the leading and trailing edges of the return pulse. MLA can in some cases infer energy and thereby surface reflectance at the laser wavelength from the returned pulses. Surficial exposures of water ice would be optically brighter than the surroundings, but persistent surface water ice would require temperatures over all seasons to remain extremely low (<110 K). Thermal models [6,7] incorporating direct and scattered radiation, Mercury s eccentric orbit, 3:2 spin-orbit resonance, and near-zero obliquity generally do not support such conditions in all permanently shadowed craters but suggest that water ice buried near the surface (<0.5 m depth) could survive for > 1 Gy. We describe measurements of reflectivity derived from MLA pulse returns. These reflectivity data show that surface materials in the shadowed regions are darker than their surroundings, enough to strongly attenuate or extinguish laser returns. Such measurements appear to rule out widespread surface exposures of water ice. We consider explanations for the apparent low reflectivity of these regions involving other types of volatile deposit.

Published
2012

144. New Morphometric Measurements of Peak-Ring Basins on Mercury and the Moon: Results from the Mercury Laser Altimeter and Lunar Orbiter Laser Altimeter

Author

Baker, David M. H, Head, James W, Prockter, Louise M, Fassett, Caleb I, Neumann, Gregory A, Smith, David E, Solomon, Sean C, Zuber, Maria T, Oberst, Juergen, Preusker, Frank, and Gwiner, Klaus

Subjects
Lunar And Planetary Science And Exploration
Abstract

Peak-ring basins (large impact craters exhibiting a single interior ring) are important to understanding the processes controlling the morphological transition from craters to large basins on planetary bodies. New image and topography data from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) and Lunar Reconnaissance Orbiter (LRO) spacecraft have helped to update the catalogs of peak-ring basins on Mercury and the Moon [1,2] and are enabling improved calculations of the morphometric properties of these basins. We use current orbital altimeter measurements from the Mercury Laser Altimeter (MLA) [3] and the Lunar Orbiter Laser Altimeter (LOLA) [4], as well as stereo-derived topography [5], to calculate the floor depths and peak-ring heights of peak-ring basins on Mercury and the Moon. We present trends in these parameters as functions of rim-crest diameter, which are likely to be related to processes controlling the onset of peak rings in these basins.

Published
2012

145. Gravity Recovery and Interior Laboratory (GRAIL) Mission: Status at the Initiation of the Science Mapping Phase

Author

Zuber, Maria T, Smith, David E, Asmar, Sami W, Alomon, Konopliv, Alexander S, Lemoine, Frank G, Melosh, H. Jay, Neumann, Gregory A, Phillips. Roger J, Solomon, Sean C, Watkins, Michael M, Wieczorek, Mark A, and Williams, James G

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Gravity Recovery And Interior Laboratory (GRAIL) mission, a component of NASA's Discovery Program, launched successfully from Cape Canaveral Air Force Station on September 10, 2011. The dual spacecraft traversed independent, low-energy trajectories to the Moon via the EL-1 Lagrange point and inserted into elliptical, 11.5-hour polar orbits around the Moon on December 31, 2011, and January 1, 2012. The spacecraft are currently executing a series of maneuvers to circularize their orbits at 55-km mean altitude. Once the mapping orbit is achieved, the spacecraft will undergo additional maneuvers to align them into mapping configuration. The mission is on track to initiate the Science Phase on March 8, 2012.

Published
2012

146. Thermal Stability of Frozen Volatiles in the North Polar Region of Mercury

Author

Paige, David A, Siegler, Matthew A, Harmon, John K, Smith, David E, Zuber, Maria T, Neumann, Gregory A, and Solomon, Sean C

Subjects
Lunar And Planetary Science And Exploration
Abstract

Earth-based radar observations have revealed the presence on Mercury of anomalously bright, depolarizing features that appear to be localized in the permanently shadowed regions of high-latitude impact craters [1]. Observations of similar radar signatures over a range of radar wavelengths implies that they correspond to deposits that are highly transparent at radar wavelengths and extend to depths of several meters below the surface [1]. Thermal models using idealized crater topographic profiles have predicted the thermal stability of surface and subsurface water ice at these same latitudes [2]. One of the major goals of the MESSENGER mission is to characterize the nature of radar-bright craters and presumed associated frozen volatile deposits at the poles of Mercury through complementary orbital observations by a suite of instruments [3]. Here we report on an examination of the thermal stability of water ice and other frozen volatiles in the north polar region of Mercury using topographic profiles obtained by the Mercury Laser Altimeter (MLA) instrument [4] in conjunction with a three-dimensional ray-tracing thermal model previously used to study the thermal environment of polar craters on the Moon [5].

Published
2012

147. Characterization of the Morphometry of Impact Craters Hosting Polar Deposits in Mercury's North Polar Region

Author

Talpe, Matthieu, J, Zuber, Maria T, Neumann, Gregory A, Mazarico, Erwan, Solomon, Sean C, and Vilas, Faith

Subjects
Lunar And Planetary Science And Exploration
Abstract

Earth-based radar images dating back two decades show that the floors of some polar craters on Mercury host radar-bright deposits that have been proposed to consist of frozen volatiles. Several hypotheses have been put forth to explain their source, including volcanic outgassing, chemical sputtering, and deposition of exogenous water ice. Calculations show that volatiles are thermally stable in permanently shadowed areas. An earlier study of the depths of north polar craters determined with photoclinometric techniques applied to Mariner 10 images yielded the conclusion that the mean ratio of crater depth d to rim-crest diameter D for craters hosting polar deposits is two-thirds that of the mean ratio for a comparable population of neighboring craters lacking such deposits. This result could be explained by (though doesn't require) the presence of a thick layer of volatiles within the polar deposit-hosting craters. Here we use altimetric profiles and topographic maps obtained by the Mercury Laser Altimeter (MLA) to revisit this analysis. MLA is an instrument on the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) spacecraft, which has been orbiting Mercury since March 2011. MLA transmits a 1064-nm laser pulse at 8 Hz during MESSENGER's trajectory over Mercury s surface. The MLA illuminates surface areas averaging between 15 m and 100 m in diameter, spaced approx 400 m apart along the spacecraft ground track. The radial precision of individual measurements is <1 m, and the current accuracy with respect to Mercury s center of mass is better than 20 m. As of mid-December 2011, MLA coverage had reached to 15 S and has yielded a comprehensive map of the topography of Mercury s northern hemisphere. The MLA data are used here to quantify the shapes of craters in the north polar region and to avoid the shadowing bias of photoclinometric techniques.

Published
2012

148. MESSENGER and Mariner 10 Flyby Observations of Magnetotail Structure and Dynamics at Mercury

Author

Slavin, James A, Anderson, Brian Jay, Baker, Daniel N, Benna, Mehdi, Boardsen, Scott A, Gold, Robert E, Ho, George C, Imber, Suzanne M, Korth, Haje, Krimigis, Stamatios, M, McNutt, Ralph L., Jr, Raines, Jim M, Sarantos, Menelaos, Schriver, David, Solomon, Sean C, Travnicek, Pavel, and Zurbuchen, Thomas H

Subjects
Geophysics, Lunar And Planetary Science And Exploration
Abstract

The first (M1), second (M2), and third (M3) MESSENGER flybys of Mercury traversed the planet's magnetotail from 1.25 to 3.25 RM downstream of the planet, where R(sub M) is Mercury's radius (2440 km). The encounters took place under northward, southward, and variable-polarity interplanetary magnetic field (IMF), respectively. The magnetic field strength B in Mercury's magnetotail follows a power law decrease with increasing antisunward distance ∣X∣, B approximately ∣X∣(sup G), with G varying from -5.4 for northward to -1.6 for southward IMF. Low-latitude boundary layers (LLBLs) containing strong northward magnetic field were detected at the tail flanks during two of the flybys. The observed thickness of the LLBL was 33% and 16% of the radius of the tail during M1 and M3, respectively, but the boundary layer was completely absent during M2. Clear signatures of tail reconnection are evident in the M2 and M3 magnetic field measurements. Plasmoids and traveling compression regions were observed during M2 and M3 with typical durations of approximately 1-3 s, suggesting diameters of approximately 500-1500 km. Overall, the response of Mercury's magnetotail to the steady southward IMF during M2 appeared very similar to steady magnetospheric convection events at Earth, which are believed to be driven by quasi-continuous reconnection. In contrast, the M3 measurements are dominated by tail loading and unloading events that resemble the large-scale magnetic field reconfigurations observed during magnetospheric substorms at Earth.

Published
2012
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149. MESSENGER Orbital Observations of Large-Amplitude Kelvin-Helmholtz Waves at Mercury's Magnetopause

Author

Sundberg, Torbjorn, Boardsen, Scott A, Slavin, James A, Anderson, Brian J, Korth, Haje, Zurbuchen, Thomas H, Raines, Jim M, and Solomon, Sean C

Subjects
Astronomy
Abstract

We present a survey of Kelvi\ n-Helmholtz (KH) waves at Mercury's magnetopause during MESSENGER's first Mercury year in orb it. The waves were identified on the basis of the well-established sawtooth wave signatures that are associated with non-linear KH vortices at the magnetopause. MESSENGER frequently observed such KH waves in the dayside region of the magnetosphere where the magnetosheath flow velocity is still sub -sonic, which implies that instability growth rates at Mercury's magnetopau~ are much larger than at Earth. We attribute these greater rates to the limited wave energy dissipation in Mercury's highly resistive regolith. The wave amplitude was often on the order of ' 00 nT or more, and the wave periods were - 10- 20 s. A clear dawn-dusk asymmetry is present in the data, in that all of the observed wave events occurred in the post-noon and dusk-side sectors of the magnetopause. This asymmetry is like ly related to finite Larmor-radius effects and is in agreement with results from particle-in-cell simulations of the instability. The waves were observed almost exclusively during periods when the north-south component of the magnetosheath magnetic field was northward, a pattern similar to that for most terrestrial KH wave events. Accompanying plasma measurements show that the waves were associated with the transport of magnetosheath plasma into the magnetosphere.

Published
2012

150. Large Impact Basins on Mercury: Global Distribution, Characteristics, and Modification History from MESSENGER Orbital Data

Author

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

Subjects
Lunar And Planetary Science And Exploration
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

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