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NARROW
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all geography including DSDP/ODP Sites and Legs
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basalts (2)
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isotopes
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stable isotopes
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metals
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alkali metals
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iron (1)
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rare earths (2)
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Moon (8)
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Lunar Prospector Program
Surface Volatiles on the Moon
Revised mineral and Mg# maps of the Moon from integrating results from the Lunar Prospector neutron and gamma-ray spectrometers with Clementine spectroscopy
The Gruithuisen region in northern Oceanus Procellarum on the Moon contains three distinctive domes interpreted as nonmare volcanic features of Imbrian age. A 4 d extravehicular activity (EVA), four-astronaut sortie mission to explore these enigmatic features and the surrounding terrain provides the opportunity to address key outstanding lunar science questions. The landing site is on the mare south of Gruithuisen 3 (36.22°N, 40.60°W). From this site, diverse geologic terrains and features are accessible, including highlands, dome material, mare basalts, multiple craters, small rilles, and a negative topographic feature of unknown origin. Preliminary mission planning is based on Clementine multispectral data, Lunar Prospector geochemical estimates, and high-resolution (0.5 m/pixel) stereo images from the Lunar Reconnaissance Orbiter Narrow Angle Camera. Science objectives for the mission include: (1) determining the nature of the domes, (2) identifying and measuring the distribution of any potassium, rare earth elements, and phosphorus (KREEP)- and thorium-rich materials, (3) collecting samples for age dating of key units to investigate the evolution of the region, and (4) deploying a passive seismic grid as part of a global lunar network. Satisfying the science objectives requires 7 h, ~20 km round-trip EVAs, and significant time driving on slopes up to ~15°.
The geology of Schrödinger basin: Insights from post– Lunar Orbiter data
The lunar south polar region (60°S–90°S) is being mapped at 1:2,500,000 scale using spacecraft data ( Lunar Reconnaissance Orbiter , Clementine , Lunar Prospector , and Lunar Orbiter ) to characterize geologic units, recognize contacts and structures, and identify impact craters (diameter [ D ] >2 km) for age dating. Most of the map area is located within the South Pole–Aitken basin, the largest (~2600 km) and oldest basin known on the Moon. At 18 km deep, South Pole–Aitken basin is believed to have exposed materials from the Moon's lower crust or upper mantle. Several large impact basins, such as Schrödinger basin ( D = 334 km), are superposed on the floor of South Pole–Aitken and may have excavated through the floor of the basin. Thus, the materials that form the primary basin structures (rim and peak-ring) of Schrödinger, as well as the materials that cover its floor, may be used as proxies for the ancient lunar crustal and/or upper-mantle materials. Characterization of the materials that constitute Schrödinger and geologic mapping of the basin have identified nine units within the Schrödinger assemblage organized into three groups: basin materials, the plains formation, and the volcanic formation. The volcanic and plains materials found on the floor of Schrödinger exhibit flat expanses with smooth to rough surfaces and are dissected by floor fractures. These materials are interpreted to consist of impact melt and/or were emplaced by effusive eruptions of mafic materials, and they are some of the youngest materials in the basin, ranging from early Imbrian to early Eratosthenian in age.