Moon Dust Mystery Solved With Help Of Apollo Mission Data | HuffPost

Moon Dust Mystery Solved With Help Of Old Apollo Data

Space.com

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A revisited trove of data from NASA's Apollo missions more than 40 years ago is helping scientists answer a lingering lunar question: How fast does moon dust build up?

The answer: It would take 1,000 years for a layer of moon dust about a millimeter (0.04 inches) thick to accumulate, the researchers found. That rate may seem slow by the standards of Earth but it's 10 times faster than scientists had believed before, and it means moon dust could pose big problems for astronauts and equipment alike.

"You wouldn't see it; it's very thin indeed," Brian O'Brien, a physicist at the University of Western Australia, said in a statement. "But, as the Apollo astronauts learned, you can have a devil of a time overcoming even a small amount of dust." [Lunar Legacy: 45 Apollo Moon Mission Photos]

Kicked-up dust was a nuisance during the Apollo missions. It clung to the astronauts' spacesuits, it smelled like gunpowder and spaceflyer Harrison Schmitt of Apollo 17, the last lunar landing mission, even reported feeling congested and complained of "lunar dust hay fever" after breathing in the particles.

This photo shows helmets and spacesuits covered in lunar dust after the last manned moonwalk, from the 1972 Apollo 17 mission.

Moon dust also wreaked havoc on some experiments. For example, it was blamed for the overheating and early failure of Apollo 11's Passive Seismic Experiment, which was intended to study "moonquakes."

O'Brien actually started his work on moon dust more than 40 years ago while he was a professor at Rice University in Houston and the principal investigator for the Dust Detector Experiment (DDE), which flew during the Apollo 11, 12, 14 and 15 missions.

Each matchbox-sized detector deployed in the experiment was equipped with three solar cells covered with a different amount of shielding against incoming radiation. By tracking the degradation of each of the cells, O'Brien hoped to determine how much damage was caused by dust and how much was caused by radiation.

NASA had lost their tapes of the data that the dust detectors collected and assumed the information from the DDE was lost forever — that is until 2006 when O'Brien told the space agency that he still had a set of backup copies. He revisited the data with his colleague Monique Hollick, a researcher also at the University of Western Australia.

"It's been a long haul," O'Brien said in a statement. "I invented [the detector] in 1966, long before Monique was even born. At the age of 79, I'm working with a 23-year old working on 46-year-old data and we discovered something exciting — it's delightful."

O'Brien and Hollick's analysis, which was detailed in the journal Space Weather, showed that the dust, rather than radiation, caused the most damage to the protected cells.

The Lunar Dust Detector, attached to the leftmost corner of this experiment package left by the Apollo 12 astronauts, made the first measurement of lunar dust accumulation. As the device's three solar panels became covered by dust, the voltage they produced dropped.

The moon has no substantial atmosphere and no wind, which means its dirt should be quite stale. As such, earlier scientific models suggested that any accumulating dust could be traced to meteor impacts and falling cosmic dust.

"But that's not enough to account for what we measured," O'Brien said. The concept of a "dust atmosphere" on the moon could explain where the particles come from, the researchers said.

According to this theory, moon dust particles on the daytime side of the moon can build a positive charge when radiation from the sun kicks electrons out of atoms of dust. But on the side of the moon that's dark, dust particles can gain a negative charge when they are bombarded with electrons from the solar wind. Where the dark and light sides meet, electric forces could levitate this charged dust high off the lunar surface, the researchers said.

"Something similar was reported by Apollo astronauts orbiting the Moon who looked out and saw dust glowing on the horizon," Hollick explained.

Sketch of the lunar sunrise seen from orbit by Apollo 17 moon landing commander Eugene Cernan in 1972.

NASA's latest moon orbiter, the Lunar Atmosphere and Dust Environment Explorer, or LADEE, which launched in September, could shed light on this levitating dust. At 155 miles (250 kilometers) above the surface of the moon, the spacecraft is looking for dust in the lunar atmosphere.

Follow Megan Gannon on Twitter and Google+. Follow us @SPACEdotcom, Facebook or Google+. Originally published on SPACE.com.

Copyright 2014 SPACE.com, a TechMediaNetwork company. All rights reserved. This material may not be published, broadcast, rewritten or redistributed. ]]>

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Before You Go

Lunar Bases And Exploration Concept Art

(01 of34)

(June 1977)--- A painting of a lunar supply base which was displayed during the NASA-sponsored Ninth Lunar and Planetary Science Conference in March 1978 in Houston.

(02 of34)

(14 March 1983) --- This artist's concept of lunar mining operations illustrates the production of liquid oxygen. Ilmenite, a fairly common oxygen rich component of lunar soil, is the material actually being mined here.

(03 of34)

(October 1984)--- An artists's rendering gives a possible preview of 21st century lunar base activity. A lunar surface crane removes a newly arrived habitation module from an expendable lunar lander.

(04 of34)

(June 1986) --- This artist's concept of a lunar base and extra-base activity was revealed during a 1986 Summer Study on possible future activities for the National Aeronautics and Space Administration. A roving vehicle similar to the one used on three Apollo missions is depicted in the foreground. The artwork was done by Dennis Davidson.

(05 of34)

(7 April 1988)--- This painting was used as a visual at an April 1988 Houston-hosted conference titled "Lunar Bases and Space Strategies of the 21st Century." A deep drill team obtains cores for petrological studies of the floor units of the young, 30-kilometers, 4200-meter crater, Aristarchus.

(06 of34)

(April 1988)--- This painting was used as a visual at an April 1988 Houston-hosted conference titled "Lunar Bases and Space Strategies of the 21st Century." Here, a surface exploration crew begins its investigation of a typical, small lava tunnel, to determine if it could serve as a natural shelter for the habitation modules of a Lunar Base.

(07 of34)

An evolutionary approach to settling the inner solar system would begin with an outpost on the Moon. Here, just three days away from Earth, we could become experienced in living and working on another planetary body. The explorer in the foreground, wearing a constant-volume, hard space suit with rotating joints, is a representative of a commerical enterprise that intends to develop and exploit extraterrestrial resources.

(08 of34)

(April 1988)--- This painting was done by Eagle Engineering artists who are working with Eagle and NASA engineers on concepts born from a NASA sponsored project called the Lunar Base Systems Study.

(09 of34)

(April 1988) --- This painting was used as a visual at an April 1988 Houston-hosted conference titled "Lunar Bases and Space Strategies of the 21st Century." Here, two jubilant scientists of an ice prospecting, lunar lander mission examine an ice-encrusted drill stem as they stand in the frigid (60 degrees K), permanently shadowed part of a south polar region crater.

(10 of34)

(April 1988) --- This painting was used as a visual at an April 1988 Houston-hosted conference titled "Lunar Bases and Space Strategies of the 21st Century." Here, a Lunar Base traverese mission crew stands on the northern tip of Vallis Schroteri during an exploration mission to the Aristarchus plateau region.

(11 of34)

(March 1989) --- An inflatable habitat similar to this could represent part of an outpost, forerunner to a permanent inhabited lunar base.

(12 of34)

(July 1989)--- With a number of studies ongoing for possible lunar expeditions, many concepts for living and working on Earth's natural satellite have been examined.

(13 of34)

(July 1989) --- With a number of studies ongoing for possible lunar explorations, many concepts for living and working on Earth's natural satellite have been examined.

(14 of34)

(22 February 1990) --- A model of a baseline lunar surface roving vehicle and accompanying astronauts on Extravehicular Activity (EVA). Part of the scene utilizes actual imagery. This view, as part of a study by the Johnson Space Center's Lunar and Mars Exploration Office does not depict existing or currently budgeted hardware.

(15 of34)

(1991) --- (Artist's concept of possible exploration programs.) An "Artemis" - class lander, capable of delivering up to 200 kilograms to the lunar surface, has delivered a teleoperated rover to the lunar surface. The rover has surveyed the landing site for an eventual human landing. The piloted vehicle is shown in the background during the final stage of its descent.

(16 of34)

(1992) --- (Artist's concept of possible exploration programs.) Lunar pioneers will encounter hazards and crises requiring new emergency procedures. Here, an antenna installer fell over a 90-foot escarpment and fractured his right femur. Responding to this situation on a "medivac" hopper, two other lunar base crew members employ a portable CAT-scan device, a holographic display, and helmet-mounted heads-up displays to determine the severity of the injury.

(17 of34)

(1993) --- (Artist's concept of possible exploration programs.) The lunar crew refills the propellant tanks on their spacecraft with oxygen produced on the Moon. This allows them to return directly to Earth, reentering the atmosphere in the conical crew module, and touching down at a prepared landing site.

(18 of34)

(1995) --- Lunar resources, such as lunar oxygen from regolith or possibly from south pole ice deposits, would increase our motivation to return to the Moon and could significantly enhance the economics of future lunar colonization.

(19 of34)

(1995) --- (Artist's concept of possible exploration programs.) Just a few kilometers from the Apollo 17 Taurus Littrow landing site, a lunar mining facility harvests oxygen from the resource-rich volcanic soil of the eastern Mare Serenitatis.

(20 of34)

(1993) --- (Artist's concept of possible exploration programs.) A teleoperated lunar oxygen plant begins production. Remotely driven surface vehicles mine and transport lunar soil to the plant, where the oxygen is extracted, liquefied, and pumped into waiting storage tanks. This image was produced for NASA by John Frassanito and Associates.

(21 of34)

(February 1995) --- (Artist's concept of possible exploration programs.) As commerce develops on the Moon, tracts of the lunar surface will be dedicated to various industries such as lunar oxygen production, communications and helium 3 production. Artwork done for NASA by Pat Rawlings, of SAIC.

(22 of34)

(February 1995) --- (Artist's concept of possible exploration programs.) A large Arecibo-like radio telescope on the Moon uses a crater for structural support.

(23 of34)

(February 1995) --- (Artist's concept of possible exploration programs.)

(24 of34)

(February 1995)---(Artist's concept of possible exploration programs.) Earth's Moon, just 3 days away, is a good place to test hardware and operations for a human mission to Mars. A simulated mission, including the landing of an adapted Mars excursion vehicle, could test many relevant Mars systems and technologies.

(25 of34)

(April 2004) --- This artist's rendering represents a concept of possible activities during future space exploration missions. It depicts a crew preparing to leave a work site on the lunar surface.

(26 of34)

(April 2004) --- This artist's rendering represents a concept of possible activities during future space exploration missions. It depicts an observatory in a crater on the dark side of the moon.

(27 of34)

(April 2004) --- This artist's rendering represents a concept of possible activities during future space exploration missions. It depicts crewmembers involved in lunar drilling.

(28 of34)

(April 2004) --- This artist's rendering represents a concept of possible activities during future space exploration missions. It depicts a human tended lunar base.

(29 of34)

(April 2004) --- This artist's rendering represents a concept of possible activities during future space exploration missions. It depicts remote operations with a pressurized rover.

(30 of34)

(April 2004) --- This artist's rendering represents a concept of possible activities during future space exploration missions. It depicts a crew involved in remote sensing on the lunar surface.

(31 of34)

(12 Jan. 2008) --- A joint project among NASA, the National Space Foundation and ILC Dover continues at the McMurdo Complex in Antarctica. Team members drill into the tundra to install a weather station adjacent to the inflatable habitat in the upper left portion of the image. NASA and NSF along with the company that manufactured the prototype inflatabe habitat are using Antarctica's frigid, harsh, isolated landscape to test a new architecture for astronaut housing on the moon.

(32 of34)

(16 January 2008) --- --- A joint project among NASA, the National Space Foundation and ILC Dover continues at the McMurdo Complex in Antarctica. Personnel with ILC Dover, the company that manufactured the prototype inflatabe habitat, work to fasten it down in the harsh environment.

(33 of34)

(February 2009) --- Crew members, attired in suits designed to protect them from the rigors of the environment, traverse the lunar surface along with two Lunar Electric Rovers (LERs) in this art work depicting return to the moon activities.

(34 of34)

(18-31 Oct. 2008) --- During tests conducted for NASA's Desert Research and Technology Studies (RATS) at Black Point Lava Flow in Arizona, engineers, geologists and astronauts came together to test NASA's new Lunar Electric Rover.

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