A lunar regolith simulant is a terrestrial material synthesized in order to approximate the chemical, mechanical, engineering, mineralogical, or particle-size distribution properties of lunar regolith.[1] Lunar regolith simulants are used by researchers who wish to research the materials handling, excavation, transportation, and uses of lunar regolith. Samples of actual lunar regolith are too scarce, and too small, for such research, and have been contaminated by exposure to Earth's atmosphere.
Early simulants
In the run-up to the Apollo program, crushed terrestrial rocks were first used to simulate the anticipated soils that astronauts would encounter on the lunar surface.[2] In some cases the properties of these early simulants were substantially different from actual lunar soil, and the issues associated with the pervasive, fine-grained, sharp dust grains on the Moon came as a surprise.[3]
Later simulants
After Apollo and particularly during the development of the Constellation program, there was a large proliferation of lunar simulants produced by different organizations and researchers. Many of these were given three-letter acronyms to distinguish them (e.g., MLS-1, JSC-1), and numbers to designate subsequent versions. These simulants were broadly divided into highlands or mare soils, and were usually produced by crushing and sieving analogous terrestrial rocks (anorthosite for highlands, basalt for mare). Returned Apollo and Luna samples were used as reference materials in order to target specific properties such as elemental chemistry or particle size distribution. Many of these simulants were criticized by prominent lunar scientist Larry Taylor for a lack of quality control and wasted money on features like nanophase iron that had no documented purpose.[4]
JSC-1 and -1A
JSC-1 (Johnson Space Center Number One) was a lunar regolith simulant that was developed in 1994 by NASA and the Johnson Space Center. Its developers intended it to approximate the lunar soil of the maria. It was sourced from a basaltic ash with a high glass content.[1]
In 2005, NASA contracted with Orbital Technologies Corporation (ORBITEC) for a second batch of simulant in three grades:[5]
JSC-1AF, fine, 27 μm average size
JSC-1A, a reproduction of JSC 1, less than 1 mm size
JSC-1AC, coarse, a distribution of sizes < 5 mm
NASA received 14 metric tons of JSC-1A, and one ton each of AF and AC in 2006. Another 15 tons of JSC-1A and 100 kg of JSC-1F were produced by ORBITEC for commercial sale, but ORBITEC is no longer selling simulants and was acquired by the Sierra Nevada Corporation. An 8-ton sand box of commercial JSC-1A is available for daily rental from the NASA Solar System Exploration Research Virtual Institute (SSERVI).[6]
JSC-1A can geopolymerize in an alkaline solutions resulting in a hard, rock-like, material.[7][8] Tests show that the maximum compressive and flexural strength of the 'lunar' geopolymer is comparable to that of conventional cements.[8]
JSC-1 and JSC-1A are now no longer available outside of NASA centers. [citation needed]
NU-LHT and OB-1
Two lunar highlands simulants, the NU-LHT (lunar highlands type) series and OB-1 (olivine-bytownite) were developed and produced in anticipation of the Constellation activities. Both of these simulants are sourced mostly from rare anorthosite deposits on the Earth. For NU-LHT the anorthosite came from the Stillwater complex, and for OB-1 it came from the Shawmere Anorthosite in Ontario. Neither of these simulants were widely distributed.
Recent simulants
Most of the previously developed lunar simulants are no longer being produced or distributed outside of NASA. Multiple companies have tried to sell regolith simulants for profit, including Zybek Advanced Products, ORBITEC, and Deep Space Industries. None of these efforts have seen much success. NASA is unable to sell simulants, or distribute unlimited amounts for free; however, NASA can award set amounts of simulant to grant winners.
Several lunar simulants have been developed recently and are either being sold commercially or are available for rent inside large regolith bins. These include the OPRL2N Standard Representative Lunar Mare Simulant[9] and Standard Representative Lunar Highland Simulant.[10] Off Planet Research also produces customized simulants for specific locations on the Moon including lunar polar icy regolith simulants that include the volatiles identified in the LCROSS mission.
Other simulants include Lunar Highlands Simulant (LHS-1)[11] and Lunar Mare Simulant (LMS-1)[12] produced and distributed by the not-for-profit Exolith Lab run out of the University of Central Florida.[13]
In 2020, a team of independent researchers from Thailand also developed the Thailand Lunar Simulant - Batch 1 (TLS-1)[18] using domestic sources - the first ever successful simulant production attempt in the country that is based on the properties of the Apollo 11 sample[19][20], further applications in the field of space and material engineering were also made using the produced simulant.[21]
^ abMcKay, David S.; Carter, James L.; Boles, Walter W.; Allen, Carlton C.; Allton, Judith H. (1994). "JSC-1: A new lunar soil simulant"(PDF). In Galloway, Rodney G.; Lokaj, Stanley (eds.). Engineering, Construction, and Operations in Space IV; Proceedings of the 4th International Conference, Albuquerque, New Mexico, February 26–March 3, 1994. Engineering, Construction, and Operations in Space IV; Albuquerque, New Mexico, February 26–March 3, 1994. Vol. 2. New York: American Society of Civil Engineers. pp. 857–866. ISBN0-87262-937-6.
^Montes, Broussard, Gongre, Simicevic, Mejia, Tham, Allouche, Davis; Evaluation of lunar regolith geopolymer binder as a radioactive shielding material for space exploration applications, Adv. Space Res. 56:1212–1221 (2015)
McKay, D. S.; Carter, J. L.; Boles, W. W.; Allen, C. C. & Alton, J. H. (1993). "JSC-1: A new lunar regolith simulant". Lunar and Planetary Science XXIV. Lunar and Planetary Science Conference. pp. 963–964. Bibcode:1993LPI....24..963M.
Klosky, J. Ledlie; Sture, Stein; Ko, Hon-Yim & Barnes, Frank (1996). "Mechanical Properties of JSC-1 Lunar Regolith Simulant". In Johnson, Stewart W. (ed.). Engineering, Construction, and Operations in Space 5: Proceedings of the Fifth International Conference on Space '96 held in Albuquerque, New Mexico, June 1–6, 1996. Fifth International Conference on Space '96 held in Albuquerque, New Mexico, June 1–6, 1996. New York: American Society of Civil Engineers. pp. 680–688. doi:10.1061/40177(207)94. ISBN0-7844-0177-2.