The future exploration of Mars will require access to the subsurface, along with acquisition of samples for scientific analysis and ground-truthing of water ice and mineral reserves for in situ resource utilization. The Icebreaker drill is an integral part of the Icebreaker mission concept to search for life in ice-rich regions on Mars. Since the mission targets Mars Special Regions as defined by the Committee on Space Research (COSPAR), the drill has to meet the appropriate cleanliness standards as requested by NASA's Planetary Protection Office. In addition, the Icebreaker mission carries life-detection instruments; and in turn, the drill and sample delivery system have to meet stringent contamination requirements to prevent false positives.
This paper reports on the development and testing of the Icebreaker drill, a 1 m class rotary-percussive drill and triple redundant sample delivery system. The drill acquires subsurface samples in short, approximately 10 cm bites, which makes the sampling system robust and prevents thawing and phase changes in the target materials. Autonomous drilling, sample acquisition, and sample transfer have been successfully demonstrated in Mars analog environments in the Arctic and the Antarctic Dry Valleys, as well as in a Mars environmental chamber. In all environments, the drill has been shown to perform at the “1-1-100-100” level; that is, it drilled to 1 m depth in approximately 1 hour with less than 100 N weight on bit and approximately 100 W of power. The drilled substrate varied and included pure ice, ice-rich regolith with and without rocks and with and without 2% perchlorate, and whole rocks. The drill is currently at a Technology Readiness Level (TRL) of 5. The next-generation Icebreaker drill weighs 10 kg, which is representative of the flightlike model at TRL 5/6. Key Words: Drilling—Sampling—Mars—Mars drilling—Subsurface exploration—Ice—Search for life. Astrobiology 13, 1166–1198.
ArvidsonR.E., BonitzR.G., RobinsonM.L., CarstenJ.L., VolpeR.A., Trebi-OllennuA., MellonM.T., ChuP.C., DavisK.R., WilsonJ.J., ShawA.S., GreenbergerR.N., SiebachK.L., SteinT.C., CullS.C., GoetzW., MorrisR.V., MingD.W., KellerH.U., LemmonM.T., SizemoreH.G., and MehtaM. (2009) Results from the Mars Phoenix lander Robotic Arm experiment. J Geophys Res, 114, doi:10.1029/2009JE003408.
2.
Bar-CohenY. and ZacnyK., editors. (2009) Drilling in Extreme Environments: Penetration and Sampling on Earth and Other Planets, Wiley-VCH, Weinheim.
3.
Bar-CohenY., BadescuM., BaoX., SherritS., ZacnyK., SadickS., and JiJ. (2010) Deep drilling and sampling via compact low-mass rotary-hammer auto-gopher. In Earth and Space 2010: Engineering, Science, Construction, and Operations in Challenging Environments, edited by SongG. and MallaR.B., American Society of Civil Engineers, Reston, VA, doi:10.1061/41096(366)94.
4.
BuckleyD. (1971) Friction, wear and lubrication in vacuum. NASA SP-277, Library of Congress Catalog Card Number. 72-174581, NASA, Washington, DC.
5.
ByrneS., DundasC.M., KennedyM.R., MellonM.T., McEwenA.S., CullS.C., DaubarI.J., SheanD.E., SeelosK.D., MurchieS.L., CantorB.A., ArvidsonR.E., EdgettK.S., ReuferA., ThomasN., HarrisonT.N., PosiolovaL.V., and SeelosF.P. (2009) Distribution of mid-latitude ground ice on Mars from new impact craters. Science, 325:1674–1676.
6.
CabrolN.A., WettergreenD.S., and the LITA Project Science Team. (2013) Life in the Atacama: science and technology pathways to the robotic search for life on Mars [abstract 1190]. In 44th Lunar and Planetary Science Conference, Lunar and Planetary Institute, Houston.
7.
ChevrierV.F., HanleyJ., and AltheideT.S. (2009) Stability of perchlorate hydrates and their liquid solutions at the Phoenix landing site, Mars. Geophys Res Lett, 36, doi:10.1029/2009GL037497.
8.
ChuP., WilsonJ., DavisK., ShiraishiL., and BurkeK. (2008) Icy Regolith Acquisition Device for the 2007 Phoenix Mars Lander. In Proceedings of the 39th Aerospace Mechanisms Symposium, NASA/CP-2010-216272, NASA Marshall Space Flight Center, Huntsville, AL.
DavéA., ThompsonS.J., McKayC.P., StokerC.R., ZacnyK., PaulsenG., MellerowiczB., GlassB., WillsonD., and BonaccorsiR. (2012) The sample handling system for the Mars Icebreaker Life mission: from dirt to data [abstract 4186]. In Concepts and Approaches for Mars Exploration, Lunar and Planetary Institute, Houston, LPI Contribution No. 1679.
11.
DavéA., ThompsonS.J., McKayC.P., StokerC.R., ZacnyK., PaulsenG., MellerowiczB., GlassB.J., WillsonD., BonaccorsiR., and RaskJ. (2013) The sample handling system for the Mars Icebreaker Life mission: from dirt to data. Astrobiology, 13:354–369.
12.
ElphicR.C., ChuP., HahnS., JamesM.R., LawrenceD.J., PrettymanT.H., JohnsonJ.B., and PodgorneyR.K. (2008) Surface and downhole prospecting tools for planetary exploration: tests of neutron and gamma ray probes. Astrobiology, 8:639–652.
13.
European Space Agency. (2012) The ExoMars drill unit. Available online at http://exploration.esa.int/science-e/www/object/index.cfm?fobjectid=43611.
14.
FletcherN.H. (1968) Surface structure of water and ice. II. A revised model. Philosophical Magazine, 18:1287–1300.
15.
FletcherN.H. (1970) The Chemical Physics of Ice, Cambridge Monographs on Physics, Cambridge University Press, Cambridge, UK.
16.
GilichinskyD., RivkinaE., ShcherbakovaV., LaurinavichuisK., and TiedjeJ. (2003) Supercooled water brines within permafrost—an unknown ecological niche for microorganisms: a model for astrobiology. Astrobiology, 3:331–341.
17.
GlassB., CannonH., HanagudS., and FrankJ. (2005) Drilling automation for subsurface planetary exploration. In Proceedings of the 8th International Symposium on Artificial Intelligence, Robotics and Automation in Space (iSAIRAS), Munich Germany, September 2005, ESA SP-603, European Space Agency, Noordwijk, the Netherlands.
GlassB.J., McKayC., ThompsonS., and ZacnyK. (2011) Automated Mars drilling for “Icebreaker.” In Aerospace Conference, 2011 IEEE, Institute of Electrical and Electronics Engineers (IEEE), Piscataway, NJ, pp 1–7.
20.
GorevanS.P., MyrickT., DavisK., ChauJ.J., BartlettP., MukherjeeS., AndersonR., SquyresS.W., ArvidsonR.E., MadsenM.B., BertelsenP., GoetzW., BinauC.S., and RichterL. (2003) Rock Abrasion Tool: Mars Exploration Rover mission. J Geophys Res, 108, doi:10.1029/2003JE002061.
21.
HechtM.H., KounavesS.P., QuinnR.C., WestS.J., YoungS.M., MingD.W., CatlingD.C., ClarkB.C., BoyntonW.V., HoffmanJ., DefloresL.P., GospodinovaK., KapitJ., and SmithP.H. (2009) Detection of perchlorate and the soluble chemistry of martian regolith at the Phoenix lander site. Science, 325:64–67.
22.
HeinsR. and FrizT. (1967) The effect of low temperature on some physical properties of rock. In Drilling and Rock Mechanics Conference, January 25–26, 1967, Austin, TX, Society of Petroleum Engineers, Richardson, TX, document ID 1714-MS.
23.
Honeybee Robotics. (2012) Ice Breaker Drill in Action. Available online at http://www.youtube.com/watch?v=fTNPokiXa0E.
24.
JanduraL. (2010) Mars Science Laboratory Sample Acquisition, Sample Processing and Handling: subsystem design and test challenges. In Proceedings of the 40th Aerospace Mechanisms Symposium, NASA/CP-2010-216272, NASA Kennedy Space Center, FL.
25.
KumarA. (1968) The effect of stress rate and temperature on the strength of basalt and granite. Geophysics, 33:501–510.
26.
LacelleD., DavilaA.F., FisherD., PollardW.H., DeWittR., HeldmannJ., MarinovaM.M., and McKayC.P. (2013) Excess ground ice of condensation-diffusion origin in University Valley, Dry Valleys of Antarctica: evidence from isotope geochemistry and numerical modeling. Geochim Cosmochim Acta, 120:280–297.
27.
LiH., YangH., ChangC., and SunX. (2001) Experimental investigation on compressive strength of frozen regolith versus strain rate. Journal of Cold Regions Engineering, 15, doi:10.1061/(ASCE)0887-381X(2001)15:2(125).
28.
MaW. and ChangX. (2002) Analyses of strength and deformation of an artificially frozen soil wall in underground engineering. Cold Regions Science and Technology, 34:11–17.
29.
MankinsJ.C. (1995) Technology Readiness Levels: a white paper. NASA Office of Space Access and Technology, Advanced Concepts Office, NASA Marshall Space Flight Center, Huntsville, AL.
30.
MarinovaM., McKayC.P., HeldmannJ.L., DavilaA.F., AndersenD.T., JacksonW.A., LacelleD., PaulsenG., PollardW.H., and ZacnyK. (2012) Distribution of the depth to ice-cemented soils in the high-elevation Quartermain Mountains, Dry Valleys of Antarctica. Antarct Sci, 25:575–582.
31.
McKayC., StokerC.R., GlassB.J., DavéA.I., DavilaA.F., HeldmannJ.L., MarinovaM.M., FairenA.G., QuinnR.C., ZacnyK.A., PaulsenG., SmithP.H., ParroV., AndersenD.T., HechtM.H., LacelleD., and PollardW.H. (2013) The Icebreaker Life mission to Mars: a search for biomolecular evidence for life. Astrobiology, 13:334–353.
32.
MellonM.T., ArvidsonR.E., SizemoreH.G., SearlsM.L., BlaneyD.L., CullS., HechtM.H., HeetT.L., KellerH.U., LemmonM.T., MarkiewiczW.J., MingD.W., MorrisR.V., PikeW.T., and ZentA.P. (2009) Ground ice at the Phoenix landing site: stability state and origin. J Geophys Res, 114, doi:10.1029/2009JE003417.
33.
MellorM. (1971) Strength and deformability of rocks at low temperatures. CRREL Research Report 294, Cold Regions Research and Engineering Lab, Hanover, NH.
34.
MellorM. (1972) Normalization of specific energy. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 9:661–663.
35.
MitchellJ.K. (1992) Fundamentals of Soil Behavior, 2nd ed., John Wiley, Hoboken, NJ.
36.
MoreschiniP., ZacnyK., and RickmanD. (2011) Downhole elemental analysis with LIBS [abstract #P43B-1667]. In AGU Fall Meeting 2011, American Geophysical Union, Washington, DC.
37.
NiebuhrD. (2007) Friction and wear behavior of engineering materials in a simulated martian (CO2) environment, a preliminary study. Wear, 263:88–92.
38.
OkonA. (2010) Mars Science Laboratory drill. In Proceedings of the 40th Aerospace Mechanisms Symposium, NASA/CP-2010-216272, NASA Kennedy Space Center, FL.
39.
ParroV., Fernández-CalvoP., Rodríguez ManfrediJ.A., Moreno-PazM., RivasL.A., García-VilladangosM., BonaccorsiR., González-PastorJ.E., Prieto-BallesterosO., SchuergerA.C., DavidsonM., Gómez-ElviraJ., and StokerC.R. (2008) SOLID2: an antibody array–based life-detector instrument in a Mars drilling simulation experiment (MARTE). Astrobiology, 8:987–999.
40.
PaulsenG., ZacnyK., CannonH., GlassB., ChuP., MummE., DavisK., Frader-ThompsonS., PetrichK., BartlettP., and GlaserD. (2006) Robotic drill systems for planetary exploration. In Space 2006, American Institute of Aeronautics and Astronautics, Reston, VA, doi:10.2514/6.2006-7512.
41.
PaulsenG., ZacnyK., McKayC., ShiraishiL., KriechbaumK., GlassB., SzczesiakM., SantoroC., CraftJ., MallaR.B., and MaksymukM. (2010) Rotary-percussive deep drill for planetary applications. In Earth and Space 2010: Engineering, Science, Construction, and Operations in Challenging Environments, edited by SongG. and MallaR.B., American Society of Civil Engineers, Reston, VA, doi:10.1061/41096(366)128.
42.
PaulsenG., ZacnyK., SzczesiakM., SantoroC., MellerowiczB., CraftJ., McKayC., GlassB., DavilaA., and MarinovaM. (2011) Testing of a 1 meter Mars Icebreaker drill in a 3.5 meter vacuum chamber and in an Antarctic Mars analog site. In AIAA SPACE 2011 Conference & Exposition, American Institute of Aeronautics and Astronautics, Reston, VA, doi:10.2514/6.2011-7236.
43.
PaulsenG., SzczesiakM., MaksymukM., SantoroC., and ZacnyK. (2012) SONIC drilling for space exploration. In Earth and Space 2012: Engineering, Science, Construction, and Operations in Challenging Environments, edited by ZacnyK., MallaR.B., and BiniendaW., American Society of Civil Engineers, Reston, VA, doi:10.1061/9780784412190.059.
44.
PetersG.H., AbbeyW., BearmanG.H., MungasG.S., SmithJ.A., AndersonR.C., DouglasS., and BeegleL.W. (2008) Mojave Mars simulant—characterization of a new geologic Mars analog. Icarus, 197:470–479.
45.
PikeW., StauferU., HechtM.H., GoetzW., ParratD., Sykulska-LawrenceH., VijendranS., and MadsenM.B. (2011) Quantification of the dry history of the martian soil inferred from in situ microscopy. Geophys Res Lett, 38, doi:10.1029/2011GL049896.
46.
ReddishD. and YasarE. (1996) A new portable rock strength index test based on specific energy of drilling. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 33:543–548.
47.
SchulsonE.M. and ForttA.L. (2012) Friction of ice on ice. J Geophys Res, 117, doi:10.1029/2012JB009219.
48.
SegerR. and GillespieV. (1974) The Viking Surface Sampler. NASA Langley Research Center, Hampton, VA. Available online at https://archive.org/detaile/nasa_techdoc_19740003574.
49.
ShcherbakovaV., RivkinaE., LaurinavichuisK., PecheritsinaS., and GilichinskyD. (2004) Physiological characteristics of bacteria isolated from water brines within permafrost. International Journal of Astrobiology, 3:37–43.
StokerC., DavillaA., DavisS., GlassB., GonzalesA., HeldmannJ., KarczJ., LemkeL., and SandersG. (2012) Ice Dragon: A mission to address science and human exploration objectives on Mars, concepts and approaches for Mars exploration, June12–14, 2012; LPI, Houston, Texas.
52.
SunshineD. (2010) Mars Science Laboratory CHIMRA: a device for processing powdered martian samples. In Proceedings of the 40th Aerospace Mechanisms Symposium, NASA/CP-2010-216272, NASA Kennedy Space Center, FL.
53.
SzwarcT., AggarwalA., HubbardS., CantwellB., and ZacnyK. (2012), A thermal model for analysis and control of drilling in icy formations on Mars. Planet Space Sci, 73:214–220.
54.
TealeR. (1965) The concept of specific energy in rock drilling. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 2:57–73.
55.
TsytovichN.A. (1975) The Mechanics of Frozen Ground, McGraw-Hill, New York.
56.
WangA., LambertJ., SobronP., and the Life in the Atacama Project Team. (2013) An instrument suite for mineral ID and biomarker seeking in Atacama [abstract 2586]. In 44th Lunar and Planetary Science Conference, Lunar and Planetary Institute, Houston.
57.
ZacnyK. and Bar-CohenY. (2010) Drilling and excavation for construction and in situ resource utilization. In Mars: Prospective Energy and Material Resources, edited by BadescuV., Springer, Berlin, pp 431–459.
58.
ZacnyK. and CooperG. (2005) Investigation of the performance of a coring bit in frozen mud under martian conditions of low temperature and pressure. J Geophys Res, 110, doi:10.1029/2004JE002341.
59.
ZacnyK. and CooperG. (2006) Considerations, constraints and strategies for drilling on Mars. Planet Space Sci, 54:345–356.
60.
ZacnyK. and CooperG. (2007a) Coring basalt rock under simulated martian atmospheric conditions. Mars, 3, doi:10.1555/mars.2007.0001.
61.
ZacnyK. and CooperG. (2007b) Friction of drill bits under martian pressure. J Geophys Res, 112, doi:10.1029/2005JE002538.
62.
ZacnyK. and CooperG. (2007c) Methods for cuttings removal from holes drilled on Mars. Mars, 3, doi:10.1555/mars.2007.00.
63.
ZacnyK.A., QuayleM.C., and CooperG.A. (2004) Laboratory drilling under martian conditions yields unexpected results. J Geophys Res, 109, doi:10.1029/2003JE002203
64.
ZacnyK., QuayleM., and CooperG. (2005) Enhancing cuttings removal with gas blasts while drilling on Mars. J Geophys Res, 110, doi:10.1029/2004JE002340
65.
ZacnyK., GlaserD., BartlettP., DavisK., and WilsonJ. (2006) Test results of core drilling in simulated ice-bound lunar regolith for the Subsurface Access System of the Construction and Resource Utilization eXplorer (CRUX) project. In Earth & Space 2006: Engineering, Construction, and Operations in Challenging Environments, proceedings of the 10th Biennial International Conference on Engineering, Construction, and Operations in Challenging Environments and Second NASA/ARO/ASCE Workshop on Granular Materials in Lunar and Martian Exploration, League City, TX, doi:10.1061/40830(188)64.
66.
ZacnyK., GlaserD., BartlettP., DavisK., and GorevanS. (2007) Drilling results in ice-bound simulated lunar regolith. AIP Conf Proc, 880, doi:10.1063/1.2437524.
67.
ZacnyK., Bar-CohenY., BrennanM., BriggsG., CooperG., DavisK., DolginB., GlaserD., GlassB., GorevanS., GuerreroJ., McKayC., PaulsenG., StanleyS., and StokerC. (2008), Drilling systems for extraterrestrial subsurface exploration. Astrobiology, 8:665–706.
68.
ZacnyK., PaulsenG., SzczesiakM., SantoroC., and CraftJ. (2010a) CRUX and IceBreaker rotary percussive lunar drills. In Space Resources Roundtable XI, June8–10, 2010, Golden, CO.
69.
ZacnyK., WilsonJ., CraftJ., AsnaniV., OravecH., CreagerC., JohnsonJ., and FongT. (2010b) Robotic lunar geotechnical tool. In Earth and Space 2010: Engineering, Science, Construction, and Operations in Challenging Environments, edited by SongG. and MallaR.B., American Society of Civil Engineers, Reston, VA, doi:10.1061/41096(366)19.
70.
ZacnyK., McKayD., BeegleL., OnstottT., MuellerR., MungasG., ChuP., and CraftJ. (2010c) Novel method of regolith sample return from extraterrestrial body using a puff of gas [paper #1082]. In 2010 IEEE Aerospace Conference, Institute of Electrical and Electronics Engineers (IEEE), Piscataway, NJ, doi:10.1109/AERO.2010.5446987.
71.
ZacnyK., CraftJ., HedlundM., ChuP., GallowayG., and MuellerR. (2010d) Investigating the efficiency of pneumatic transfer of JSC-1a lunar regolith simulant in vacuum and lunar gravity during parabolic flights. In AIAA Space 2010, American Institute of Aeronautics and Astronautics, Reston, VA, doi:10.2514/6.2010-8702.
72.
ZacnyK., PaulsenG., and GlassB. (2010e) Field testing of planetary drill in the Arctic. In AIAA Space 2010, American Institute of Aeronautics and Astronautics, Reston, VA, doi:10.2514/6.2010-8701.
73.
ZacnyK., PaulsenG., and SzczesiakM. (2011) Challenges and methods of drilling on the Moon and Mars [paper #1002]. In 2011 IEEE Aerospace Conference, Institute of Electrical and Electronics Engineers (IEEE), Piscataway, NJ, doi:10.1109/AERO.2011.5747261.
74.
ZacnyK., PaulsenG., MellerowiczB., CraftJ., McKayC., GlassB., DavilaA., MarinovaM., DaveA., and ThompsonS. (2012a) The Icebreaker: Mars drill and sample delivery system [abstract 1153]. In 43rd Lunar and Planetary Science Conference, Lunar and Planetary Institute, Houston.
75.
ZacnyK., HedlundM., HermanJ., CraftJ., SmytheB., and McKayC. (2012b) Sample crushing, sieving, metering, and distribution system. In 2012 IEEE Aerospace Conference, Institute of Electrical and Electronics Engineers (IEEE), Piscataway, NJ, doi:10.1109/AERO.2012.6187062.
76.
ZacnyK., PaulsenG., SzczesiakM., CraftJ., ChuP., McKayC., GlassB., DavilaA., MarinovaM., PollardW., and JacksonW. (2013a) LunarVader: development and testing of a lunar drill in a vacuum chamber and in the lunar analog site of the Antarctica. J Aerosp Eng, 26, doi:10.1061/(ASCE)AS.1943-5525.0000212.
77.
ZacnyK., PaulsenG., MellerowiczB., Bar-CohenY., BeegleL., SherritS., BadescuM., CorsettiF., CraftJ., IbarraY., BaoX., and LeeH.J. (2013b) Wireline deep drill for exploration of Mars, Europa, and Enceladus. In 2013 IEEE Aerospace Conference, Institute of Electrical and Electronics Engineers (IEEE), Piscataway, NJ, doi:10.1109/AERO.2013.6497189.
78.
ZacnyK., PaulsenG., MellerowiczB., CraftJ., WettergreenD., and CabrolN. (2013c) Life in the Atacama: the drill and sample delivery system [abstract 1332]. In 44th Lunar and Planetary Science Conference, Lunar and Planetary Institute, Houston.
