Wednesday, August 19, 2009

Nanotech advances in lunar dust mitigation

Hard to duplicate: one unique constituent grain of lunar dust, plasma fused by micrometeoroid bombardment and doped with nanophase iron from cosmic rays, the lunar exosphere presents a danger to humans and equipment, particularly seals and other moving parts. The familiar blast of the descent stage of the Apollo lunar modules is now believed to have lofted some lunar dust as high as the orbiting Command Service module orbiting overhead, and even to escape velocities. The arrival of Apollo 12 turned out to be the source of all traceable "damage" found when retrieved parts of Surveyor 3 were returned to Earth by Conrad & Bean in 1969.

In 2007 the National Academies of Science Space Studies Board listed lunar dust mitigation among the hairiest problems in need of attention before extended human activity on the Moon. Apollo 17 Geologist Sen. Harrison Schmitt, on the other hand, while not ignoring the threat to personnel and equipment posed by the dusty lunar exosphere, has advised lunar exploration enthusiasts not to be too worried. He is a proponent of sintering of lunar dust, essentially melting dusty areas into hard-tops, and taking advantage of the unique, difficult to duplicate presence of nanophase iron in most lunar dust for a variety of technologies.

Be that as it may, an interim grade given NASA on its progress with the Board's recommendations in 2008 grade NASA efforts in lunar dust mitigation and in situ resource utilization highly, while grading the Agency's progress as problematic.

Now, Ronald Pirich, John Weir, Dennis Leyble and Michael DiGiuseppe of the Technology Development Department at Northrop Grumman Aerospace Systems in Bethpage, New York, have proposed a new family of coating systems provides self-decontamination against dust and biological pathogens for future space exploration.

Dust contamination is a serious problem for equipment and vehicles for space exploration. For example, the Moon's dust (lunar regolith) is chemically composed of several elements and compounds, and lunar ‘weathering’ has left the soil with a relatively fine texture compared to the size distribution of terrestrial dust particles. Previous NASA investigations indicated a lunar-regolith deposition rate of approximately 0.3% coverage per day, although this will vary both geographically and as a function of time. In addition, the Moon's surface is electrostatically charged by its interaction with the local plasma environment and solar UV- and x-ray-induced photoemission of electrons. The lunar thermal environment poses unique challenges to coatings since it is characterized by large temperature variations, long hot and cold soak times, and reduced heat-rejection capability caused by the presence of regolith. Dust gathers on photonic sensors, inhibiting motion and data gathering. Devices that require transparency to light for maximum efficiency (such as solar photovoltaic power systems, video cameras, and optical or IR detectors) also suffer from dust accumulation (see Figure 1). Some scientists have even suggested another potential hazard, that equipment might inadvertently capture extraterrestrial bacteria or spores, possibly leading to catastrophic contamination of human habitats.

The Apollo astronauts noted that their extravehicular-mobility suits were worn through the outer layer. Gauge dials were so abraded during the Apollo 16 mission that they were unreadable. The sun shade on Harrison Schmitt's face plate was so scratched that he could not see in certain directions. NASA strongly believes that these abrasion problems must be solved, especially for very light-transmission-sensitive photonic lenses and coatings. Dust contaminant particles can absorb or scatter light either out of or into certain pixels, thus giving rise to dark and bright artifacts, respectively.

Only very localized and weak magnetic fields exist on the lunar surface, leaving it essentially directly exposed to the impact of solar UV and x-rays, solar-wind plasma, and energetic particles. The lack of an atmosphere results in positive (negative) charging of the environment in sunlight (shadow) regions. This leads to potentials that can vary over orders of magnitude in response to changing solar illumination and plasma conditions. At the macroscale, contaminant adhesion caused by surface (van der Waals) forces are very small and can be easily perturbed by other external forces. However, on nanoscales van der Waals forces can be significant. In general, ionizing radiation does not affect these intermolecular forces unless the surface-molecular structure is changed, since van der Waals interactions are always present between molecules. They only depend on the number of electrons in a given molecule and the distance between molecules. Ionizing radiation would primarily affect the surface chemistry of the material used for the coating material.

In cooperation with NASA, small businesses, and leading universities, we are developing a family of self-cleaning and anti-contamination coating systems that provide self-decontamination against dust, chemical agents, and biological pathogens, as well as toxic industrial compounds and materials and other environmental foulants. They are self-cleaning because contaminants are easily removed from surfaces by solar wind or mechanical vibration. More importantly for lunar-dust mitigation, we have shown that these coatings can be designed using low-surface-energy materials that reduce all particle adhesion very significantly (see Figure 2). In addition, we are developing a family of hybrid catalytic coatings that present a unique and paradigm-changing approach to dust mitigation using biocidal and chemical neutralization features. Dust accumulation on sensors, solar cells, and thermal radiators gradually reduces their effectiveness until they no longer generate or dissipate enough energy to sustain operation of equipment. Our new coating systems have the potential to minimize these effects. NASA believes it is also critical to prevent accumulation of dust and other contaminants on vehicles and mechanical equipment to prevent performance degradation and reduce maintenance. These coatings offer the potential to simplify decontamination procedures by neutralizing unintentionally captured micro-organisms or harmful chemicals on surfaces of structures and equipment during assembly—both on earth and in extraterrestrial environments—preventing inadvertent and possibly catastrophic contamination.

We are designing an integrated approach to solving the dust problems—including the required coatings properties—as a function of ionizing radiation, temperature, and space-contamination effects. We are developing and testing hydrophilic, hydrophobic, and hybrid-coating self-cleaning techniques, as well as a new approach incorporating various catalytic mechanisms (stoichiometric, photo-, and electrocatalytic) for decontamination in the lunar environment.

Controlling and excluding dust particles from photonic systems will be of paramount importance to ensure the safety of future space exploration missions, reliable operation of solar arrays, radiators, sensors, internal/external structural surfaces, and other photonic-related equipment. Development of self-cleaning coatings to mitigate dust contamination accumulation is critical to meeting extended exploration mission requirements. One potential component of this solution includes a range of coatings that possess the required photonic performance and reduce extraterrestrial cleaning requirements, while providing lower maintenance and overall mission costs.

18 August 2009, SPIE Newsroom. DOI: 10.1117/2.1200908.1744

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