Abstract
Because of the low-gravity on the Moon and Mars, landslides there have characteristics that are very different from those observed in a conventional gravity environment. These include highly marked dynamic characteristics, evidence of fierce movement at high speed and on a large scale. One of the key problems in extra-planetary exploration is understanding the behavior of granular material flows under the influence of low gravity. A drop-tower testing system situated in Beijing has been developed and used to investigate granular flow in a microgravity environment. A set of granular flow tests was performed in both normal and microgravity environments, during which the configurations of sand flows were captured by the monitoring system. Preliminary results provide fundamental information for the future exploration of planetary landscapes.
References
Andrade SD, de Vries BV (2010) Structural analysis of the early stages of catastrophic stratovolcano flank-collapse using analogue models. Bull Volcanol 72(7):771–789
Anken R, Forster A, Baur U, Feucht I, Hilbig R (2006) Otolith asymmetry and kinetotic behaviour of fish at high-quality microgravity: A drop-tower experiment. Adv Space Res 38:1032–1036
Bart GD (2007) Comparison of small lunar landslides and Martian gullies. Icarus 187:417–421
Bonini M, Corti G, Del Ventisette C, Manetti P, Mulugeta G, Sokoutis D (2007) Modelling the lithospheric rheology control on the Cretaceous rifting in West Antarctica. Terra Nova 19(5):360–366
Colwell JE (2003) Low velocity impacts into dust: results from the COLLIDE-2 microgravity experiment. Icarus 164:188–196
Corti G (2004) Centrifuge modelling of the influence of crustal fabrics on the development of transfer zones: insights into the mechanics of continental rifting architecture. Tectonophysics 384(1–4):191–208
Del Ventisette C, Garfagnoli F, Ciampalini A, Battistini A, Gigli G, Moretti S, Casagli N (2012) An integrated approach to the study of catastrophic debris-flows: geological hazard and human influence. Nat Hazard Earth Syst Sci 12(9):2907–2922
Del Ventisette C, Montanari D, Sani F, Bonini M (2006) Basin inversion and fault reactivation in laboratory experiments. J Struct Geol 28(11):2067–2083
Del Ventisette C, Montanari D, Sani F, Bonini M, Corti G (2007) Reply to comment by J. Wickham on “Basin inversion and fault reactivation in laboratory experiments”. J Struct Geol 29(8):1417–1418
Fukuoka H, Wang GH, Sassa K, Wang FW, Matsumoto T (2004) Earthquake-induced rapid long-traveling flow phenomenon: May 2003 Tsukidate landslide in Japan. Landslides 1:151–155
Gabet EJ, Mudd SM (2006) The mobilization of debris flows from shallow landslides. Geomorphology 74:207–218
Huang Y, Chen W, Liu J (2012a) Secondary geological hazard analysis in Beichuan after the Wenchuan earthquake and recommendations for reconstruction. Environ Earth Sci 66(4):1001–1009
Huang Y, Zhang WJ, Xu Q, Xie P, Hao L (2012b) Run-out analysis of flow-like landslides triggered by the Ms 8.0 2008 Wenchuan earthquake using smoothed particle hydrodynamics. Landslides 9(2):275–283
Joulain P, Vietoris T, Torero J (2001) Gas-gas and gas-solid laminar flat plate diffusion flame in microgravity: structure and stability. Microgravity Sci Technol 13:3–7
Kobayashi T, Ochiai H, Yasufuku N, Omine K, Aoki S, Kanamori H, Matsui K, Miyahara A (2006) Load-settlement characteristics of Japanese lunar soil simulant in partial gravity. Space Resources Roundtable VIII, Colorado, USA, pp 37–38
Kundrot CE, Judge RA, Pusey ML, Snell EH (2001) Microgravity and macromolecular crystallography. Cryst Growth Des 1:87–99
Lucchitta BK (1978) A large landslide on Mars. GSA Bull 89:1601–1609
Masursky H, Colton GW, El-Baz F (1978) Apollo over the moon: A view from orbit (NASA SP-362). National Aeronautics and Space Administration. Washington, D.C., Chapter 5
NASA (2005) Giant Landslide on Iapetus. http://www.nasaimages.org/luna/servlet/detail/NVA2%7E1%7E1%7E217%7E100255:Giant-Landslide-on-Iapetus?sort=Title%252CDate. Updated 7 January 2005
Neuffer DP, Schultz RA (2006) Mechanisms of slope failure in Valles Marineris, Mars. Q J Eng Geol Hydrogeol 39(3):227–240
Sassa K, Fukuoka H, Wang FW, Wang GH (2005) Dynamic properties of earthquake-induced large-scale rapid landslides within past landslide masses. Landslides 2:125–134
Schlacht IL, Brambillasca S, Birke H (2009) Color perception in microgravity conditions: The results of CROMOS parabolic flight experiment. Microgravity Sci Technol 21:21–30
Schreurs G, Buiter SJH, Boutelier D, Corti G, Costa E, Cruden AR, Daniel JM, Hoth S, Koyi H, Kukowski N, Lohrmann J, Ravaglia A, Schlische RW, Withjack MO, Yamada Y, Cavozzi C, Del Ventisetti C, Elder Brady JA, Hoffmann-Rothe A, Mengus JM, Montanari D, Nilfouroshan F (2006) Analogue benchmarks of shortening and extension experiments. Geol Soc Special Publ 253:1–27
Sosio R, Crosta GB, Frattini R (2007) Field observations, rheological testing and numerical modelling of a debris-flow event. Earth Surf Process Landf 32:290–306
Willman BM, Boles WW, McKay DS, Allen CC (1995) Properties of lunar soil simulant JSC-1. J Aerosp Eng 8:77–87
Yin YP, Wang FW, Sun P (2009) Landslide hazards triggered by the 2008 Wenchuan earthquake, Sichuan, China. Landslides 6:139–152
Acknowledgments
This work was supported by the Key Laboratory of Microgravity, Institute of Mechanics, Chinese Academy of Sciences, the National Natural Science Foundation of China (Grant No. 41072202), the Program for New Century Excellent Talents in University (Grant No. NCET-11-0382), the Changjiang Scholars and Innovative Research Team in University (Grant No. PCSIRT, IRT1029), the National Science Found for Distinguished Young Scholars of China (Grant No. 41225011), and the Chang Jiang Scholars Program of China.
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Huang, Y., Mao, W. First results derived from a drop-tower testing system for granular flow in a microgravity environment. Landslides 10, 493–501 (2013). https://doi.org/10.1007/s10346-013-0403-7
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DOI: https://doi.org/10.1007/s10346-013-0403-7