Lunar water
Lunar water is water that is present on the Moon. Liquid water cannot persist at the Moon's surface, and water vapor is decomposed by sunlight, with hydrogen quickly lost to outer space. However, scientists have conjectured since the 1960s that water ice could survive in cold, permanently shadowed craters at the Moon's poles. Water molecules are also detected in the thin layer of gases above the lunar surface.[1][2]
Water (H2O), and the chemically related hydroxyl group (-OH), can also exist in forms chemically bound as hydrates and hydroxides to lunar minerals (rather than free water), and evidence strongly suggests that this is indeed the case in low concentrations over much of the Moon's surface.[3] In fact, adsorbed water is calculated to exist at trace concentrations of 10 to 1000 parts per million.[4] Inconclusive evidence of free water ice at the lunar poles had accumulated during the second half of the 20th century from a variety of observations suggesting the presence of bound hydrogen.
On 18 August 1976 the Soviet Luna 24 probe landed at Mare Crisium, took samples from the depths of 118, 143 and 184 cm of the lunar regolith and then took them to Earth. In February 1978 it was published that laboratory analysis of these samples shown they contained 0.1% water by mass.[5][6][7] Spectral measurements shown minima near 3, 5 and 6 µm, distinctive valence-vibration bands for water molecules, with intensities two or three times larger than the noise level.[8]
Moon Impact Probe (MIP), an instrument on board Chandrayaan-1 was developed by ISRO in India and was able to discover water on the Moon just before impact[9], This was 3 months before NASA's M3 (on the same satellite) confirmed presence of water. The announcement of this discovery was not made until NASA confirmed it. This made India the first country to confirm the abundance of water in the polar regions of the moon, using a self-developed instrument, on a self-developed satellite, using home grown launch vehicle and technology.
On 24 September 2009 it was reported that the NASA's Moon Mineralogy Mapper (M3) spectrometer onboard India's ISRO Chandrayaan-1 probe had detected absorption features near 2.8–3.0 μm (0.00011–0.00012 in) on the surface of the Moon. For silicate bodies, such features are typically attributed to hydroxyl- and/or water-bearing materials.[10] In August 2018, NASA confirmed that M3 showed water ice is present on the surface at the Moon poles.[11][12]
Water may have been delivered to the Moon over geological timescales by the regular bombardment of water-bearing comets, asteroids and meteoroids [13] or continuously produced in situ by the hydrogen ions (protons) of the solar wind impacting oxygen-bearing minerals.[14]
The search for the presence of lunar water has attracted considerable attention and motivated several recent lunar missions, largely because of water's usefulness in rendering long-term lunar habitation feasible.
History of observations
20th century
- Apollo Program
The possibility of ice in the floors of polar lunar craters was first suggested in 1961 by Caltech researchers Kenneth Watson, Bruce C. Murray, and Harrison Brown.[15] Although trace amounts of water were found in lunar rock samples collected by Apollo astronauts, this was assumed to be a result of contamination, and the majority of the lunar surface was generally assumed to be completely dry.[16][7] However, a 2008 study of lunar rock samples revealed evidence of water molecules trapped in volcanic glass beads.[17]
The first direct evidence of water vapor near the Moon was obtained by the Apollo 14 ALSEP Suprathermal Ion Detector Experiment, SIDE, on March 7, 1971. A series of bursts of water vapor ions were observed by the instrument mass spectrometer at the lunar surface near the Apollo 14 landing site.[18]
- Luna 24
In February 1978 Soviet scientists M. Akhmanova, B. Dement'ev, and M. Markov of the Vernadsky Institute of Geochemistry and Analytical Chemistry published a paper claiming a detection of water fairly definitively.[5][6] Their study showed that the samples returned to Earth by the 1976 Soviet probe Luna 24 contained about 0.1% water by mass, as seen in infrared absorption spectroscopy (at about 3 μm (0.00012 in) wavelength), at a detection level about 10 times above the threshold.[7]
- Clementine
A proposed evidence of water ice on the Moon came in 1994 from the United States military Clementine probe. In an investigation known as the 'bistatic radar experiment', Clementine used its transmitter to beam radio waves into the dark regions of the south pole of the Moon.[19] Echoes of these waves were detected by the large dish antennas of the Deep Space Network on Earth. The magnitude and polarisation of these echoes was consistent with an icy rather than rocky surface, but the results were inconclusive,[20] and their significance has been questioned.[21][22] Earth-based radar measurements were used to identify the areas that are in permanent shadow and hence have the potential to harbour lunar ice: Estimates of the total extent of shadowed areas poleward of 87.5 degrees latitude are 1,030 and 2,550 square kilometres (400 and 980 sq mi) for the north and south poles, respectively.[23] Subsequent computer simulations encompassing additional terrain suggested that an area up to 14,000 square kilometres (5,400 sq mi) might be in permanent shadow.[24]
- Lunar Prospector
The Lunar Prospector probe, launched in 1998, employed a neutron spectrometer to measure the amount of hydrogen in the lunar regolith near the polar regions.[25] It was able to determine hydrogen abundance and location to within 50 parts per million and detected enhanced hydrogen concentrations at the lunar north and south poles. These were interpreted as indicating significant amounts of water ice trapped in permanently shadowed craters,[26] but could also be due to the presence of the hydroxyl radical (•OH) chemically bound to minerals. Based on data from Clementine and Lunar Prospector, NASA scientists have estimated that, if surface water ice is present, the total quantity could be of the order of 1–3 cubic kilometres (0.24–0.72 cu mi).[27][28] In July 1999, at the end of its mission, the Lunar Prospector probe was deliberately crashed into Shoemaker crater, near the Moon's south pole, in the hope that detectable quantities of water would be liberated. However, spectroscopic observations from ground-based telescopes did not reveal the spectral signature of water.[29]
- Cassini–Huygens
More suspicions about the existence of water on the Moon were generated by inconclusive data produced by Cassini–Huygens mission,[30] which passed the Moon in 1999.
21st century
- Deep Impact
In 2005, observations of the Moon by the Deep Impact spacecraft produced inconclusive spectroscopic data suggestive of water on the Moon. In 2006, observations with the Arecibo planetary radar showed that some of the near-polar Clementine radar returns, previously claimed to be indicative of ice, might instead be associated with rocks ejected from young craters. If true, this would indicate that the neutron results from Lunar Prospector were primarily from hydrogen in forms other than ice, such as trapped hydrogen molecules or organics. Nevertheless, the interpretation of the Arecibo data do not exclude the possibility of water ice in permanently shadowed craters.[31] In June 2009, NASA's Deep Impact spacecraft, now redesignated EPOXI, made further confirmatory bound hydrogen measurements during another lunar flyby.[16]
- Kaguya
As part of its lunar mapping programme, Japan's Kaguya probe, launched in September 2007 for a 19-month mission, carried out gamma ray spectrometry observations from orbit that can measure the abundances of various elements on the Moon's surface.[32] Japan's Kaguya probe's high resolution imaging sensors failed to detect any signs of water ice in permanently shaded craters around the south pole of the Moon,[33] and it ended its mission by crashing into the lunar surface in order to study the ejecta plume content.[34]
- Chang'e 1
The People's Republic of China's Chang'e 1 orbiter, launched in October 2007, took the first detailed photographs of some polar areas where ice water is likely to be found.[35]
- Chandrayaan-1
India's ISRO spacecraft Chandrayaan-1 released the Moon Impact Probe (MIP) that impacted Shackleton Crater, of the lunar south pole, at 20:31 on 14 November 2008 releasing subsurface debris that was analysed for presence of water ice. During its 25-minute descent, the impact probe's Chandra's Altitudinal Composition Explorer (CHACE) recorded evidence of water in 650 mass spectra gathered in the thin atmosphere above the Moon's surface and hydroxyl absorption lines in reflected sunlight.[36][37]
On September 25, 2009, NASA declared that data sent from its M3 confirmed the existence of hydrogen over large areas of the Moon's surface,[30] albeit in low concentrations and in the form of hydroxyl group ( · OH) chemically bound to soil.[10][38][39] This supports earlier evidence from spectrometers aboard the Deep Impact and Cassini probes.[16][40][41] On the Moon, the feature is seen as a widely distributed absorption that appears strongest at cooler high latitudes and at several fresh feldspathic craters. The general lack of correlation of this feature in sunlit M3 data with neutron spectrometer H abundance data suggests that the formation and retention of OH and H2O is an ongoing surficial process. OH/H2O production processes may feed polar cold traps and make the lunar regolith a candidate source of volatiles for human exploration.
Although M3 results are consistent with recent findings of other NASA instruments onboard Chandrayaan-1, the discovered water molecules in the Moon's polar regions is not consistent with the presence of thick deposits of nearly pure water ice within a few meters of the lunar surface, but it does not rule out the presence of small (<∼10 cm (3.9 in)), discrete pieces of ice mixed in with the regolith.[42] Additional analysis with M3 published in 2018 had provided more direct evidence of water ice near the surface within 20° latitude of both poles. In addition to observing reflected light from the surface, scientists used M3's near-infrared absorption capabilities in the permanently shadowed areas of the polar regions to find absorption spectra consistent with ice. At the north pole region, the water ice is scattered in patches, while it is more concentrated in a single body around the south pole. Because these polar regions do not experience the high temperatures (greater than 373 Kelvin), it was postulated that the poles act as cold traps where vaporized water is collected on the Moon.[43][44]
On March 2010, it was reported that the Mini-SAR on board Chandrayaan-1 had discovered more than 40 permanently darkened craters near the Moon's north pole that are hypothesized to contain an estimated 600 million metric tonnes of water-ice.[45][46] The radar's high CPR is not uniquely diagnostic of either roughness or ice; the science team must take into account the environment of the occurrences of high CPR signal to interpret its cause. The ice must be relatively pure and at least a couple of meters thick to give this signature. [46] The estimated amount of water ice potentially present is comparable to the quantity estimated from the previous mission of Lunar Prospector's neutron data.[46]
- Lunar Reconnaissance Orbiter | Lunar Crater Observation and Sensing Satellite
On October 9, 2009, the Centaur upper stage of its Atlas V carrier rocket was directed to impact Cabeus crater at 11:31 UTC, followed shortly by the NASA's Lunar Crater Observation and Sensing Satellite (LCROSS) spacecraft that flew through the ejecta plume.[47] LCROSS detected a significant amount of hydroxyl group in the material thrown up from a south polar crater by an impactor;[48] [49] this may be attributed to water-bearing materials – what appears to be "near pure crystalline water-ice" mixed in the regolith.[45][49][50] What was actually detected was the chemical group hydroxyl ( · OH), which is suspected to be from water,[3] but could also be hydrates, which are inorganic salts containing chemically-bound water molecules. The nature, concentration and distribution of this material requires further analysis;[49] chief mission scientist Anthony Colaprete has stated that the ejecta appears to include a range of fine-grained particulates of near pure crystalline water-ice.[45] A later definitive analysis found the concentration of water to be "5.6 ± 2.9% by mass".[51]
The Mini-RF instrument onboard the Lunar Reconnaissance Orbiter (LRO) observed the plume of debris from the impact of the LCROSS orbiter, and it was concluded that the water ice must be in the form of small (< ~10 cm), discrete pieces of ice distributed throughout the regolith, or as thin coating on ice grains.[52] This, coupled with monostatic radar observations, suggest that the water ice present in the permanently shadowed regions of lunar polar craters is unlikely to be present in the form of thick, pure ice deposits.[52][53][54]
The data acquired by the Lunar Exploration Neutron Detector (LEND) instrument onboard LRO show several regions where the epithermal neutron flux from the surface is suppressed, which is indicative of enhanced hydrogen content.[55] Further analysis of LEND data suggests that water content in the polar regions is not directly determined by the illumination conditions of the surface, as illuminated and shadowed regions do not manifest any significant difference in the estimated water content.[56] According to the observations by this instrument alone, "the permanent low surface temperature of the cold traps is not a necessary and sufficient condition for enhancement of water content in the regolith."[56]
LRO laser altimeter's examination of the Shackleton crater at the [lunar south pole]] suggests up to 22% of the surface of that crater is covered in ice.[57]
- Melt inclusions in Apollo 17 samples
In May 2011, Erik Hauri et al. reported[58] 615-1410 ppm water in melt inclusions in lunar sample 74220, the famous high-titanium "orange glass soil" of volcanic origin collected during the Apollo 17 mission in 1972. The inclusions were formed during explosive eruptions on the Moon approximately 3.7 billion years ago.
This concentration is comparable with that of magma in Earth's upper mantle. While of considerable selenological interest, this announcement affords little comfort to would-be lunar colonists. The sample originated many kilometers below the surface, and the inclusions are so difficult to access that it took 39 years to detect them with a state-of-the-art ion microprobe instrument.
Possible water cycle
Production
Lunar water has two potential origins: water-bearing comets (and other bodies) striking the Moon, and in situ production. It has been theorized that the latter may occur when hydrogen ions (protons) in the solar wind chemically combine with the oxygen atoms present in the lunar minerals (oxides, silicates etc.) to produce small amounts of water trapped in the minerals' crystal lattices or as hydroxyl groups, potential water precursors.[59] (This mineral-bound water, or hydroxylated mineral surface, must not be confused with water ice.)
The hydroxyl surface groups (X–OH) formed by the reaction of protons (H+) with oxygen atoms accessible at oxide surface (X=O) could further be converted in water molecules (H2O) adsorbed onto the oxide mineral's surface. The mass balance of a chemical rearrangement supposed at the oxide surface could be schematically written as follows:
- 2 X–OH → X=O + X + H2O
or,
- 2 X–OH → X–O–X + H2O
where "X" represents the oxide surface.
The formation of one water molecule requires the presence of two adjacent hydroxyl groups, or a cascade of successive reactions of one oxygen atom with two protons. This could constitute a limiting factor and decreases the probability of water production, if the proton density per surface unit is too low.
Trapping
Solar radiation would normally strip any free water or water ice from the lunar surface, splitting it into its constituent elements, hydrogen and oxygen, which then escape to space. However, because of the only very slight axial tilt of the Moon's spin axis to the ecliptic plane (1.5 °), some deep craters near the poles never receive any sunlight, and are permanently shadowed (see, for example, Shackleton crater, and Whipple crater). The temperature in these regions never rises above about 100 K (about −170 ° Celsius),[60] and any water that eventually ended up in these craters could remain frozen and stable for extremely long periods of time — perhaps billions of years, depending on the stability of the orientation of the Moon's axis.[17][20]
While the ice deposits may be thick, they are most likely mixed with the regolith, possibly in a layered formation.[61]
Transport
Although free water cannot persist in illuminated regions of the Moon, any such water produced there by the action of the solar wind on lunar minerals might, through a process of evaporation and condensation, migrate to permanently cold polar areas and accumulate there as ice, perhaps in addition to any ice brought by comet impacts.[16]
The hypothetical mechanism of water transport / trapping (if any) remains unknown: indeed lunar surfaces directly exposed to the solar wind where water production occurs are too hot to allow trapping by water condensation (and solar radiation also continuously decomposes water), while no (or much less) water production is expected in the cold areas not directly exposed to the Sun. Given the expected short lifetime of water molecules in illuminated regions, a short transport distance would in principle increase the probability of trapping. In other words, water molecules produced close to a cold, dark polar crater should have the highest probability of surviving and being trapped.
To what extent, and at what spatial scale, direct proton exchange (protolysis) and proton surface diffusion directly occurring at the naked surface of oxyhydroxide minerals exposed to space vacuum (see surface diffusion and self-ionization of water) could also play a role in the mechanism of the water transfer towards the coldest point is presently unknown and remains a conjecture.
Uses
The presence of large quantities of water on the Moon would be an important factor in rendering lunar habitation cost-effective since transporting water (or hydrogen and oxygen) from Earth would be prohibitively expensive. If future investigations find the quantities to be particularly large, water ice could be mined to provide liquid water for drinking and plant propagation, and the water could also be split into hydrogen and oxygen by solar panel-equipped electric power stations or a nuclear generator, providing breathable oxygen as well as the components of rocket fuel. The hydrogen component of the water ice could also be used to draw out the oxides in the lunar soil and harvest even more oxygen.
Analysis of lunar ice would also provide scientific information about the impact history of the Moon and the abundance of comets and asteroids in the early Inner Solar System.
Ownership
The hypothetical discovery of usable quantities of water on the Moon may raise legal questions about who owns the water and who has the right to exploit it. The United Nations Outer Space Treaty does not prevent the exploitation of lunar resources, but does prevent the appropriation of the Moon by individual nations and is generally interpreted as barring countries from claiming ownership of in-situ resources.[62][63] However most legal experts agree that the ultimate test of the question will arise through precedents of national or private activity. Some private companies such as Shackleton Energy Company are already asserting their right to own whatever resources they remove and/or benefit from the Moon or asteroids through their own effort, risk and investment. The Moon Treaty specifically stipulates that exploitation of lunar resources is to be governed by an "international regime", but this treaty has been ratified by only a few of the major space-faring nations.[64]
Tribute
On 13 November 2009, the discovery of water on the Moon was celebrated with a Google Doodle.[65]
See also
- Missions mapping lunar water
- Chandrayaan-1 lunar orbiter
- Chandrayaan-2 lunar orbiter and rover
- Lunar Flashlight solar sail orbiter
- Lunar IceCube lunar orbiter
- LunaH-Map lunar obiter
- Lunar Reconnaissance Orbiter
References
- ^ "Atmosphere of the Moon". space.com. Retrieved 2015-05-25.
- ^ "Is There an Atmosphere on the Moon? | NASA". nasa.gov. Retrieved 2015-05-25.
- ^ a b Lucey, Paul G. (23 October 2009). "A Lunar Waterworld". Science. 326 (5952): 531–532. Bibcode:2009Sci...326..531L. doi:10.1126/science.1181471. PMID 19779147.
- ^ Clark, Roger N. (23 October 2009). "Detection of Adsorbed Water and Hydroxyl on the Moon". Science. 326 (5952): 562–564. Bibcode:2009Sci...326..562C. doi:10.1126/science.1178105. PMID 19779152.
- ^ a b Akhmanova, M; Dement'ev, B; Markov, M (February 1978). "Water in the regolith of Mare Crisium (Luna-24)?". Geokhimiya (in Russian) (285).
- ^ a b Akhmanova, M; Dement'ev, B; Markov, M (1978). "Possible Water in Luna 24 Regolith from the Sea of Crises". Geochemistry International. 15 (166).
- ^ a b c Crotts, Arlin (October 2011). "Water on The Moon, I. Historical Overview". Astronomical Review. 6 (8): 4–20. arXiv:1205.5597. Bibcode:2011AstRv...6h...4C. doi:10.1080/21672857.2011.11519687. Retrieved 2012-10-03.
By the early 1970s the Dry Moon was settled science, especially among lunar geologists in the United States. Had that gone differently, the last mission of the Moon Race, by the Soviets, might have changed everything. It discovered water within the Moon. Instead it was ignored. On August 9, 1976, Luna 24 launched toward the Moon on a Proton rocket, and nine days later landed safely in the southern part of the unexplored Mare Crisium... What it brought back was very special. The core sample was found by scientists M. Akhmanova, B. Dement'ev, and M. Markov of the Vernadsky Institute of Geochemistry and Analytic Chemistry to contain about 0.1% water by mass, as seen in infrared absorption spectroscopy (at about 3 microns wavelength), at a detection level about 10 times above the threshold.
- ^ Markov, M.N.; Petrov, V.S.; Akhmanova, M.V.; Dement'ev, B.V. (1980). "Infrared reflection spectra of the moon and lunar soil". In Rycroft, M.J. (ed.). Space Research Proceedings of the Open Meetings of the Working Groups on Physical Sciences of the Twenty-Second Plenary Meeting of COSPAR. Twenty-Second Plenary Meeting of COSPAR. COSPAR Colloquia Series. Vol. 20. Bangalore, India (published 1 January 1980). pp. 189–192. doi:10.1016/S0964-2749(13)60040-2. ISBN 978-0-08-024437-2.
Fig. 3 shows the diffuse reflection spectra and scattering polar diagrams for two wavelengths (2.2 and 4.5 µm) for samples returned to Earth by Luna 24... Fig. 3 also shows slight minima near 3, 5 and 6 µm. These absorption bands are rather well identified by the valence bands and vibrations of a water molecule. The intensity of these bands (two or three times larger than the noise level) is a maximum for the sample taken from the depth of 143 cm, and becomes less at 184 cm; it is comparable with the noise level at 118 cm. A comparison with basalt spectra with known water concentrations allows an estimate to be made of the water content in the sample; at a depth of 143 cm, this is 0.1%... We have taken all the necessary precautions to protect the samples of lunar soil from atmospheric water, and thus have confidence in our results. The 5.5 to 7.5 µm structure in the reflection spectrum obtained by Saljut 5 may also favour the lunar origin of the water.
- ^ https://en.wikipedia.org/wiki/Chandrayaan-1.
{{cite web}}
: Missing or empty|title=
(help) - ^ a b Pieters, C. M.; Goswami, J. N.; Clark, R. N.; Annadurai, M.; Boardman, J.; Buratti, B.; Combe, J. -P.; Dyar, M. D.; Green, R.; Head, J. W.; Hibbitts, C.; Hicks, M.; Isaacson, P.; Klima, R.; Kramer, G.; Kumar, S.; Livo, E.; Lundeen, S.; Malaret, E.; McCord, T.; Mustard, J.; Nettles, J.; Petro, N.; Runyon, C.; Staid, M.; Sunshine, J.; Taylor, L. A.; Tompkins, S.; Varanasi, P. (2009). "Character and Spatial Distribution of OH/H2O on the Surface of the Moon Seen by M3 on Chandrayaan-1". Science. 326 (5952): 568–572. Bibcode:2009Sci...326..568P. doi:10.1126/science.1178658. PMID 19779151.
- ^ https://www.jpl.nasa.gov/news/news.php?feature=7218 Ice Confirmed at the Moon's Poles
- ^ Water on the Moon: Direct evidence from Chandrayaan-1's Moon Impact Probe. Published on 2010/04/07.
- ^ Elston, D.P. (1968) "Character and Geologic Habitat of Potential Deposits of Water, Carbon and Rare Gases on the Moon", Geological Problems in Lunar and Planetary Research, Proceedings of AAS/IAP Symposium, AAS Science and Technology Series, Supplement to Advances in the Astronautical Sciences., p. 441
- ^ "NASA – Lunar Prospector". lunar.arc.nasa.gov. Archived from the original on 2016-09-14. Retrieved 2015-05-25.
- ^ Watson, K., B. C. Murray, and H. Brown (1961), The Behavior of Volatiles on the Lunar Surface, J. Geophys. Res., 66(9), 3033–3045.
- ^ a b c d "It's Official: Water Found on the Moon", Space.com, 23 September 2009
- ^ a b Moon Once Harbored Water, Lunar Lava Beads Show, Scientific American, July 9, 2008
- ^ Freeman, J.W., Jr., H.K. Hills., R.A. Lindeman, and R.R. Vondrak, Observations of Water Vapor at the Lunar Surface, The Moon, 8, 115–128, 1973
- ^ The Clementine bistatic radar experiment — Science
- ^ a b Clementine Probe Archived July 24, 2008, at the Wayback Machine
- ^ Simpson, Richard A.; Tyler, G. Leonard (1999). "Reanalysis of Clementine bistatic radar data from the lunar South Pole". Journal of Geophysical Research. 104 (E2): 3845. Bibcode:1999JGR...104.3845S. doi:10.1029/1998JE900038. hdl:2060/19990047963.
- ^ Campbell, Donald B.; Campbell, Bruce A.; Carter, Lynn M.; Margot, Jean-Luc; Stacy, Nicholas J. S. (2006). "No evidence for thick deposits of ice at the lunar south pole" (PDF). Nature. 443 (7113): 835–7. Bibcode:2006Natur.443..835C. doi:10.1038/nature05167. PMID 17051213.
- ^ Margot, J. L. (1999). "Topography of the Lunar Poles from Radar Interferometry: A Survey of Cold Trap Locations". Science. 284 (5420): 1658–1660. Bibcode:1999Sci...284.1658M. CiteSeerX 10.1.1.485.312. doi:10.1126/science.284.5420.1658. ISSN 0036-8075. PMID 10356393.
- ^ Linda, Martel (June 4, 2003). "The Moon's Dark, Icy Poles".
- ^ "Eureka! Ice found at lunar poles". August 31, 2001. Archived from the original on December 9, 2006.
- ^ Lunar Prospector Science Results NASA
- ^ Prospecting for Lunar Water, NASA
- ^ Neutron spectrometer results Archived January 17, 2009, at the Wayback Machine
- ^ No water ice detected from Lunar Prospector, NASA website
- ^ a b Kemm, Kelvin (October 9, 2009). "Evidence of water on the Moon, Mars alters planning for manned bases". Engineering News. Retrieved 2009-10-09.
- ^ Paul Spudis (2006). "Ice on the Moon". The Space Review. Retrieved 2013-09-27.
- ^ Kaguya Gamma Ray Spectrometer, JAXA
- ^ "Japan's now-finished lunar mission found no water ice". Spaceflight Now. July 6, 2009. Retrieved 2013-09-27.
- ^ "Japanese probe crashes into Moon". BBC News. 2009-06-11. Retrieved 2013-09-27.
- ^ "Who's Orbiting the Moon?", NASA, February 20, 2008
- ^ "Chandrayaan team over the Moon". The Hindu. 2008-11-15.
- ^ "MIP detected water on Moon way back in June: ISRO Chairman". The Hindu. 2009-09-25.
- ^ "Spacecraft see 'damp' Moon soils", BBC, 24 September 2009
- ^ Leopold, George (2009-11-13). "NASA confirms water on Moon". Retrieved 2009-11-18.
{{cite news}}
: Cite has empty unknown parameter:|pagesf=
(help) - ^ "Moon crash will create six-mile plume of dust as Nasa searches for water", The Times, October 3, 2009
- ^ Discovery of water on Moon boosts prospects for permanent lunar base, The Guardian, 24 September 2009
- ^ Neish, C. D.; D. B. J. Bussey; P. Spudis; W. Marshall; B. J. Thomson; G. W. Patterson; L. M. Carter. (13 January 2011). "The nature of lunar volatiles as revealed by Mini-RF observations of the LCROSS impact site". Journal of Geophysical Research: Planets. 116 (E01005): 8. Bibcode:2011JGRE..116.1005N. doi:10.1029/2010JE003647. Retrieved 2012-03-26.
the Mini-RF instruments on ISRO's Chandrayaan-1 and NASA's Lunar Reconnaissance Orbiter (LRO) obtained S band (12.6 cm (5.0 in)) synthetic aperture radar images of the impact site at 150 and 30 m resolution, respectively. These observations show that the floor of Cabeus has a circular polarization ratio (CPR) comparable to or less than the average of nearby terrain in the southern lunar highlands. Furthermore, <2% of the pixels in Cabeus crater have CPR values greater than unity. This observation is not consistent with the presence of thick deposits of nearly pure water ice within a few meters of the lunar surface, but it does not rule out the presence of small (<∼10 cm (3.9 in)), discrete pieces of ice mixed in with the regolith.
- ^ Rincon, Paul (21 August 2018). "Water ice 'detected on Moon's surface'". BBC. Retrieved 21 August 2018.
- ^ "Direct evidence of surface exposed water ice in the lunar polar regions". Proceedings of the National Academy of Sciences of the United States of America. 115 (36): 8907–8912. 20 August 2018. doi:10.1073/pnas.1802345115. PMC 6130389. PMID 30126996.
{{cite journal}}
: Unknown parameter|authors=
ignored (help) - ^ a b c "Ice deposits found at Moon's pole". BBC News, 2 March 2010.
- ^ a b c "NASA Radar Finds Ice Deposits at Moon's North Pole". NASA. March 2010. Retrieved 2012-03-26.
- ^ LCROSS mission overview Archived 2009-06-13 at the Wayback Machine, NASA
- ^ Lakdawalla, Emily (13 November 2009). "LCROSS Lunar Impactor Mission: "Yes, We Found Water!"". The Planetary Society. Archived from the original on 22 January 2010. Retrieved 2010-04-13.
- ^ a b c Dino, Jonas; Lunar Crater Observation and Sensing Satellite Team (November 13, 2009). "LCROSS Impact Data Indicates Water on Moon". NASA. Retrieved 2009-11-14.
- ^ Moon River: What Water in the Heavens Means for Life on Earth, by Randall Amster, The Huffington Post, November 30, 2009.
- ^ Colaprete, A.; Schultz, P.; Heldmann, J.; Wooden, D.; Shirley, M.; Ennico, K.; Hermalyn, B.; Marshall, W; Ricco, A.; Elphic, R. C.; Goldstein, D.; Summy, D.; Bart, G. D.; Asphaug, E.; Korycansky, D.; Landis, D.; Sollitt, L. (22 October 2010). "Detection of Water in the LCROSS Ejecta Plume". Science. 330 (6003): 463–468. Bibcode:2010Sci...330..463C. doi:10.1126/science.1186986. PMID 20966242.
- ^ a b "Mini-RF Monostatic Radar Observations of Permanently Shadowed Crater Floors." L. M. Jozwiak, G. W. Patterson, R. Perkins. Lunar ISRU 2019: Developing a New Space Economy Through Lunar Resources and Their Utilization. July 15–17, 2019, Columbia, Maryland.
- ^ Nozette, Stewart; Spudis, Paul; Bussey, Ben; Jensen, Robert; Raney, Keith; et al. (January 2010). "The Lunar Reconnaissance Orbiter Miniature Radio Frequency (Mini-RF) Technology Demonstration". Space Science Reviews. 150 (1–4): 285–302. Bibcode:2010SSRv..150..285N. doi:10.1007/s11214-009-9607-5.
- ^ Neish, C. D.; D. B. J. Bussey; P. Spudis; W. Marshall; B. J. Thomson; G. W. Patterson; L. M. Carter. (13 January 2011). "The nature of lunar volatiles as revealed by Mini-RF observations of the LCROSS impact site". Journal of Geophysical Research: Planets. 116 (E01005): 8. Bibcode:2011JGRE..116.1005N. doi:10.1029/2010JE003647. Retrieved 2012-03-26.
- ^ "Hydrogen Mapping of the Lunar South Pole Using the LRO Neutron Detector Experiment LEND". science.sciencemag.org. doi:10.1126/science.1185696. Retrieved 2019-10-07.
- ^ a b Water in the Moon's polar areas: Results of LEND neutron telescope mapping. I. G. Mitrofanov, A. B. Sanin, M. L. Litvak. Doklady Physics, February 2016, Volume 61, Issue 2, pp 98–101. doi:10.1134/S1028335816020117
- ^ Researchers Estimate Ice Content of Crater at Moon's South Pole (NASA)
- ^ Hauri, Erik; Thomas Weinreich; Alberto E. Saal; Malcolm C. Rutherford; James A. Van Orman (26 May 2011). "High Pre-Eruptive Water Contents Preserved in Lunar Melt Inclusions". Science Express. 10 (1126): 213–215. Bibcode:2011Sci...333..213H. doi:10.1126/science.1204626. ISSN 1095-9203.
- ^ L.F.A. Teodoro; V.R. Eke; R. Elphic. "Lunar Hydrogen Distribution after KAGUYA(SELENE)" (PDF). 2009 Annual Meeting of LEAG (2009). Retrieved 2009-11-18.
{{cite journal}}
: Unknown parameter|last-author-amp=
ignored (|name-list-style=
suggested) (help) - ^ Ice on the Moon, NASA
- ^ The Moon and Mercury May Have Thick Ice Deposits. Bill Steigerwald and Nancy Jones, NASA. 2 August 2019.
- ^ Treaty on Principles Governing the Activities of States in the Exploration and Use of Outer Space, including the Moon and Other Celestial Bodies ("Outer Space Treaty") Archived 2011-02-22 at WebCite, UN Office for Outer Space Affairs
- ^ "Moon Water: A Trickle of Data and a Flood of Questions", space.com, March 6, 2006
- ^ Agreement Governing the Activities of States on the Moon and Other Celestial Bodies ("Moon Treaty") Archived 2008-05-14 at the Wayback Machine, UN Office for Outer Space Affairs
- ^ "Discovery of Water on the Moon". Google. 2009-11-13.
External links
- Ice on the Moon — NASA Goddard Space Flight Center
- Fluxes of fast and epithermal neutrons from Lunar Prospector: Evidence for water ice at the lunar poles — Science
- Moon has a litre of water for every tonne of soil — Times Online
- Unambiguous evidence of water on the Moon — Slashdot Science Story
- CubeSat for investigating ice on the Moon — SPIE Newsroom