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Mare Nectaris

Mare Nectaris, Latin for "Sea of Nectar," is a basaltic plain on the , measuring approximately 340 kilometers in and centered at 15.2° S, 34.6° E. It occupies the floor of the ancient Nectaris multiring impact basin, which spans about 860 kilometers and was formed by a massive or strike roughly 3.9 to 4.1 billion years ago during the Nectarian period of lunar history. The mare's dark, smooth appearance results from subsequent volcanic flooding by iron- and magnesium-rich basaltic lavas that erupted through the fractured crust in at least two main episodes, around 3.8 billion years ago and again near 3.0 billion years ago, creating a layer up to 1 kilometer thick. Geologically, Mare Nectaris exhibits heterogeneous compositions, dominated by pyroxene-rich basalts with significant concentrations, particularly evident in spectral data from orbital missions showing strong absorptions at 1000 nm and weaker ones at 2000 nm. The basin's eastern rim is marked by the Montes Pyrenaeus , uplifted anorthositic highlands that contrast sharply with the mare's darker and provide insights into the impact's structural effects. Notable features include the -rich, dark-haloed Beaumont L on the eastern flank and the partially flooded Fracastorius along the southern edge, which highlight the mare's volcanic and impact history. As a for NASA's former , Mare Nectaris offers potential for studying early lunar volcanism and resources.

Geography

Location and Extent

Mare Nectaris is a located on the , positioned in the southeastern quadrant close to the eastern limb, making it fully visible from under favorable conditions. It is centered at approximately 15.2° S and 34.6° E , with extents spanning from 9.9° S to 21.1° S in and 28.8° E to 39.7° E in . The mare occupies the central floor of the Nectaris impact basin, an ancient structure measuring 860 km in . The basaltic plains of Mare Nectaris themselves cover a roughly circular area with a of about 340 km. This surface area is estimated at approximately 84,000 km², representing a significant but not complete infilling of the basin floor. Mare Nectaris is bordered by other major lunar features, including to the north and to the east. To the west, it adjoins highland terrain along the basin rim, while the southern boundary is defined by the prominent Altai Scarp .

Topography and Surface Features

Mare Nectaris features a relatively flat floor, with elevations ranging from approximately -2,500 to -3,000 meters relative to the lunar datum, contrasting sharply with the surrounding rugged highlands that rise up to +2,000 meters. This topography reflects the impact 's structure, where the smooth basaltic plains form the low-lying interior, while the encircling terrain exhibits significant relief due to the basin's multi-ring formation. The basin's overall diameter measures about 860 kilometers, creating a distinct circular depression visible in global lunar topographic models. Prominent landforms define the mare's boundaries. To the east, Montes Pyrenaeus forms a rugged mountain range approximately 250 kilometers long and up to 3 kilometers high, composed of uplifted anorthositic highlands that mark the basin's eastern rim. On the southern side, the Altai Scarp (Rupes Altai) stands as a major escarpment about 480 kilometers in length and up to 1 kilometer in height, serving as the outermost ring of the Nectaris basin and separating the mare from fractured, cratered highlands. Key craters punctuate the rims: Theophilus, a 100-kilometer-diameter of Copernican age, intrudes the northern rim with its well-preserved walls and central peaks; Catharina, measuring 99 kilometers across, lies on the eastern rim amid eroded highlands; and Fracastorius, a 121-kilometer flooded on the southern rim, opens into the mare like a bay. Internally, the mare's surface displays subtle tectonic features, including minor rilles and wrinkle ridges that indicate post-emplacement contraction of the layers. These linear structures, often arcuate and up to several kilometers long, deform the smooth plains and align with broader patterns of lunar crustal shortening. At the northeastern margin, Sinus Asperitatis—a rough-textured bay spanning 219 kilometers—transitions into the mare, characterized by uneven terrain and partial basalt flooding that contrasts with the smoother central floor. From , Mare Nectaris appears as a dark, circular patch visible to the under clear conditions, especially during waxing gibbous phases, evoking its historical designation as a "" due to the uniform, low-albedo basaltic plains that dominate its appearance.

Basin Formation

Mare Nectaris originated from a massive impact approximately 3.9 billion years ago, forming an 860 km diameter multiring on the Moon's near side. The impact generated a transient cavity estimated at 300–400 km wide and less than 90 km deep, excavating material from depths up to about 30 km and excavating a volume on the order of 6–9 million cubic kilometers. This event exemplifies the mechanics of large impacts, where the projectile's energy vaporized and melted target rocks, creating a complex structure through propagation and material displacement. The basin's structure features uplifted and overturned anorthositic crust forming concentric rings, including the prominent Montes Pyrenaeus as the inner ring and the Altai Scarp as part of the southwestern rim. blankets extend hundreds of kilometers outward, with well-preserved deposits to the south and west, while northern and eastern areas were later modified; these were later modified by younger impacts, such as the Imbrium basin, through secondary cratering and overlapping deposits. Chronologically, the Nectaris impact marks the onset of the Nectarian period in lunar stratigraphy, positioning it as an intermediate event between the older South Pole-Aitken basin and the younger Imbrium basin. Evidence for this formation derives from geologic mapping using orbital imagery and spectroscopy, which reveal shocked and brecciated highland rocks around the rim, corroborated by samples showing impact-derived breccias. Subsequent volcanic flooding partially filled the basin with mare basalts.

Mare Basalts and Composition

Mare Nectaris was partially flooded by basaltic lavas that erupted primarily from fissures in a flood-style manner, occurring approximately 3.4 to 3.8 billion years ago and covering a substantial portion of the floor, estimated at around 90,000 km² within the larger 860 km-diameter . The mare basalts reflect at least two main volcanic episodes, with older, high-alumina flows around 3.7–3.8 and younger low-titanium units around 3.4–3.5 . This volcanic infilling followed the basin's formation and exploited structural weaknesses, such as the depressed floor and surrounding fractures, to channel magma upward and spread across the terrain. The resulting mare deposits obscure much of the underlying impact features while preserving evidence of multiple eruptive episodes through subtle spectral and topographic variations. The basalts composing Mare Nectaris are predominantly low-titanium (low-Ti) varieties characterized by high-alumina content, distinguishing them from higher-Ti basalts in other lunar . Key constituent minerals include anorthite-rich , (primarily pigeonite and ), and , which dominate the rock fabric and contribute to the unit's to intermediate . Iron oxide (FeO) abundances range from 12.5 to 16 wt%, while titanium dioxide (TiO₂) contents remain below 3 wt%, consistent with remote sensing data from Clementine UVVIS and Lunar Prospector Gamma Ray Spectrometer missions that identify low-Fe, low-Ti signatures across the . Compositional variations exist within the mare, including patches of high-alumina basalts enriched in rare earth elements (REE), often termed HAREE types, which exhibit elevated alumina (>11 wt% Al₂O₃) and distinct patterns indicative of unique sources. These variations are revealed through spectral analyses showing 900–950 nm features linked to compositions, with some units displaying pigeonite dominance. Remote sensing data further correlate these signatures with samples, such as the high-alumina basalt clast in 60639 and fragment 60053,2-9, suggesting that ejecta from Mare Nectaris contributed low-Ti, high-Al material to the landing site. Individual lava flows in Mare Nectaris range from 100 to 500 m in thickness, forming stacked sequences that achieve total mare fill depths of 0.5–3 km. Beneath the visible mare surface, possible cryptomaria—buried basaltic layers mantled by —may exist, evidenced by dark-halo craters like Beaumont L that expose olivine-rich subsurface materials matching mare compositions.

Age and Stratigraphy

The formation of the Mare Nectaris impact basin occurred approximately 3.85–3.92 Ga, establishing it as the type locality for the onset of the Nectarian period in lunar stratigraphy. This age estimate derives from crater size-frequency distribution (CSFD) analyses of basin floor units and blankets, calibrated against radiometric dates from nearby samples, as well as stratigraphic superposition relations showing Nectaris overlying highland materials but underlying deposits from younger basins like Imbrium. Isochrons from CSFD measurements yield N(20) values of approximately 135 ± 14 craters ≥20 km per 10^6 km² for Nectarian terrains, supporting this chronology. The of Mare Nectaris features a foundational layer of breccias and impact melt from the basin-forming event, including the Janssen Formation characterized by lineated ejecta and secondary craters. These are overlain by a sequence of mare basalts that partially fill the basin to depths of 0.5–3 km, followed by a veneer of post-mare impact craters and rays. In the broader lunar timeline, this sequence postdates basin formations (e.g., South Pole-Aitken) but predates the Orientale basin (~3.80 Ga), with Nectaris serving as a key marker for the Nectarian-Imbrian transition. Mare basalt emplacement in Mare Nectaris occurred predominantly during the Imbrian period, with model ages spanning 3.4–3.7 Ga based on CSFD dating of spectrally distinct flow units, though some peripheral or cryptomare deposits extend to as young as 3.2 Ga. No volcanism is recorded in the Eratosthenian (~3.2–1.1 Ga) or Copernican (<1.1 Ga) periods, consistent with the basin's overall antiquity and lack of low-crater-density resurfacing. Absent direct samples from the mare, these ages rely on remote sensing correlations with dated Apollo and Luna basalts, emphasizing CSFD isochrons that plot along late Imbrian production functions (e.g., N(10) ~100 for older units).

Nomenclature and Mapping

Origin of the Name

The dark patches on the Moon's surface, including the region later known as Mare Nectaris, were first observed through a by in late 1609, who described them as vast, uneven areas contrasting with brighter highlands, though he did not assign names to specific features. The name "Mare Nectaris," meaning "Sea of Nectar" in Latin, was coined by the Italian astronomer and Jesuit priest in 1651 as part of his influential lunar map published in the Almagestum Novum. This designation drew inspiration from 17th-century associating the visibility of this region during the first quarter moon with good weather, with "nectar" evoking sweetness and positivity in Riccioli's meteorological-themed approach to labeling the Moon's basaltic plains as imagined seas. Riccioli's nomenclature reflected a broader tradition among European astronomers of evoking ancient maritime and mythological imagery for the Moon's , transforming telescopic observations of dark, sea-like expanses into evocative Latin terms that blended scientific description with classical . His system, developed with collaborator Francesco Grimaldi, became a foundational standard for lunar in the , though it evolved over time. The name Mare Nectaris was formally standardized and approved by the (IAU) in 1935 as part of its efforts, retaining Riccioli's original Latin designation while ensuring consistency across global astronomical usage.

Historical Mapping

The earliest depictions of the lunar surface, including the region now known as Mare Nectaris, appeared in Johannes Hevelius's Selenographia published in 1647, where it was vaguely represented as part of the broader southern dark patches without distinct boundaries or . This work marked the first comprehensive lunar atlas, relying on telescopic sketches that captured general contrasts but lacked precision due to observational limitations. A significant advancement came with Giovanni Battista Riccioli's 1651 map in Almagestum Novum, which first clearly labeled Mare Nectaris as "Mare Nectaris" and outlined its approximate oval shape amid surrounding features. Riccioli's chart, co-authored with Francesco Grimaldi, introduced a systematic that named nearby craters after prominent figures, establishing a foundational framework for future selenographers. In the , Wilhelm Beer and Heinrich Mädler's 1837 Mappa Selenographica refined the boundaries of Mare Nectaris through meticulous micrometric measurements, depicting it as a distinct, roughly triangular with improved positional accuracy relative to earlier works. This four-sheet map, at a scale of 38 inches to the lunar diameter (approximately 1:3.6 million), corrected scale errors from prior maps and incorporated over 300 named features. Building on this, Friedrich Julius Schmidt's 1878 Charte der Gebirge des Mondes provided even finer details, including micrometer-based drawings of craters such as along its northern edge, enhancing the resolution of internal structures to about 1-2 km. Schmidt's 25-sheet atlas, with an assembled diameter of about 2 meters (scale approximately 1:1.75 million), represented the zenith of pre-photographic . The 20th century saw standardization through institutional efforts, with the U.S. Air Force Aeronautical Chart and Information Center's Lunar Aeronautical Chart (LAC) series, including the 1963 edition covering Mare Nectaris (LAC 78), providing consistent coordinates and topographic shading for pre-Apollo mission planning. NASA-supported compilations in the early further harmonized these charts with telescopic data. Post-1970, the (IAU) gazetteer formalized feature names, including those for Mare Nectaris, drawing from historical precedents like Blagg and Müller's 1935 compilation to resolve lingering disputes. Throughout the pre-spacecraft era, mapping Mare Nectaris faced challenges from limited telescopic resolution, often capping detail at 1 km or coarser, leading to distortions in scale and feature alignment that were progressively mitigated by micrometry techniques. These methods, involving precise angular measurements with filar micrometers, enabled corrections to earlier inaccuracies but still relied on subjective sketching under varying and illumination.

Observation and Exploration

Telescopic and Earth-Based Observations

Mare Nectaris, located at approximately 15° S and 35° E , is best observed from during the first quarter phase of the , roughly days 4 to 7 after new Moon, when the terminator illuminates its western margins and enhances against surrounding highlands. Its apparent angular size spans about 0.13° (8 arcminutes) across the 860 km diameter, appearing as a prominent dark patch visible even to the under clear conditions, with high due to the low of its basaltic fill compared to adjacent terrains. Telescopic viewing requires a minimum aperture of 50-100 mm to discern the basic oval outline and major boundaries, such as the northern contact with , while apertures of 200 mm or larger resolve individual craters like (101 km diameter) and subtle internal features. The Altai Scarp, a prominent 500 km-long fault along the southeastern rim rising up to 2 km, appears as a bright, linear ridge under favorable seeing conditions, even in modest 100 mm telescopes during early morning illumination. Historical Earth-based studies from the 19th and early 20th centuries, including systematic lunar sections by astronomers like those documented in the U.S. Geological Survey's telescopic programs, described Mare Nectaris as a remarkably uniform dark plain with few prominent elevations, aiding early stratigraphic classifications of pre-Imbrian basins. Modern amateur observations employing imaging, such as those compiled by the Association of Lunar and Planetary Observers, reveal finer details like subtle variations across the mare floor, including brighter rays from distant impacts and darker craters, which were imperceptible in earlier visual surveys. Observing Mare Nectaris faces challenges from lunar , which minimally affects its central position but can slightly shift edge visibility by up to 7° over the cycle, and atmospheric turbulence, which typically limits ground-based resolution to around 1 arcsecond even at prime sites, blurring finer ridges and craterlets.

Spacecraft Imagery and Data

The Lunar Orbiter missions, conducted between 1966 and 1967, provided the first detailed photographic coverage of Mare Nectaris. Lunar Orbiter 4 captured broad nearside images, including the mare, during 30 orbits, achieving resolutions up to 10 times better than Earth-based telescopes and contributing to approximately 80% global lunar mapping. Lunar Orbiter 5 followed with targeted high-resolution frames of the region, selecting scientifically significant sites for 174 exposures over 69 orbits, revealing surface textures and crater distributions essential for early geological assessments. Surveyor 7, landing in January 1968 on the ejecta blanket of Tycho crater in the lunar highlands, transmitted over 21,000 images of the surrounding rough terrain but did not directly image Mare Nectaris, approximately 1,500 km away; however, its highland data offered contextual insights into nearby ejecta that may overlap with Nectarian-age materials. Subsequent missions in the 1990s advanced compositional analysis. The Clementine mission's Ultraviolet/Visible (UVVIS) camera in 1994 acquired multispectral data at 100 m/pixel resolution, identifying up to three basalt units in Mare Nectaris: a dominant high-alumina unit with 12.5–16 wt% FeO and 1.5–4 wt% TiO₂, plus remnants of a mid-titanium capping flow at 18–19 wt% FeO and 6–7 wt% TiO₂, derived from spectral profiles of impact crater ejecta. Lunar Prospector's gamma-ray spectrometer in 1998 detected elevated thorium concentrations (≥3 μg/g) in the eastern nearside maria, including Mare Nectaris, linking it to broader Procellarum KREEP Terrane influences and suggesting subsurface enrichment from ancient impacts. Japan's () mission from 2007 to 2009 enhanced topographic mapping with its Terrain Camera, achieving 10 m panchromatic images that outlined the mare's floor and rim structures, while the Lunar Radar Sounder probed subsurface interfaces up to several hundred meters deep at 75 m range . Modern orbiters have delivered unprecedented detail. NASA's (LRO), operational since 2009 and continuing through 2025, uses the Lunar Reconnaissance Orbiter Camera (LROC) Narrow Angle Camera to capture 0.5 m/pixel images, such as those at the Mare Nectaris-Montes Pyrenaeus boundary, revealing secondary craters, fractures, and contrasts that highlight infilling by dark over fractured highlands; recent analyses as of 2023 have refined mappings of dark-halo craters using LROC data. India's (2008) Moon Mineralogy Mapper provided hyperspectral data (450–3000 nm at ~280 m/pixel), confirming low-titanium through - and olivine-dominated spectra with moderate 1000 nm and 2000 nm absorptions. (2019) extended this with Imaging Infra-Red Spectrometer observations, refining low-Ti mappings across the mare. China's missions in the 2010s, including Chang'e-2's and gamma-ray spectrometers, contributed global compositional data showing moderate and levels in Mare Nectaris, consistent with dry, KREEP-influenced . Despite extensive orbital coverage, no have landed directly in Mare Nectaris, yielding no in-situ samples or surface analyses. The region's Nectarian geology and potential for accessing ancient basin materials have positioned it as a candidate for future sample-return missions under NASA's , with proposals emphasizing compact in-situ instruments for targeted collection.

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    We have been considering sample return mission from the Moon during the Artemis era and have developed compact in-situ analysis instruments for geologic ...