Pyrite in sliding mud: A potential indicator of landslide development

Guodong Zheng; Liang Shouyun; Lang Yuhua; Ma Xiangxian; Liang Mingliang; Xiang Wei

doi:10.1007/s12583-010-0148-3

Journal of Earth Science ›› 2010, Vol. 21 ›› Issue (6) : 954 -960. DOI: 10.1007/s12583-010-0148-3

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Pyrite in sliding mud: A potential indicator of landslide development

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Abstract

A new principle of geochemical conditions within a landslide slip zone is presented based on the concept of a self-sealing closed system for which newly formed pyrite should be considered as a potential indicator. Once slip zones occur, a series of water-rock interactions may take place, particularly, a change in redox conditions simultaneously with progression of the landslide. This change induces weathering of the debris and bed rocks, and leads to accumulation of newly formed sliding mud within the slip zone. Pyrite formation along with clay mineral accumulation occurs under a weak alkaline-strong reducing environment along with landslide development. Thus, formation of neogenetic pyrite, iron speciation, and clay mineralization are all important factors for a better understanding of landslide progression.

Keywords

pyrite / sliding mud / self-closed system / landslide development

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Guodong Zheng, Liang Shouyun, Lang Yuhua, Ma Xiangxian, Liang Mingliang, Xiang Wei. Pyrite in sliding mud: A potential indicator of landslide development. Journal of Earth Science, 2010, 21(6): 954-960 DOI:10.1007/s12583-010-0148-3

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References

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[1]	Berner R. A.. Sedimentary Pyrite Formation. American Journal of Sciences, 1970, 268(1): 1-23.

[2]	Berner R. A.. Sedimentary Pyrite Formation: An Update. Geochimica et Cosmochimica Acta, 1984, 48(4): 605-615.

[3]	Chigira M., Oyama T.. Mechanism and Effect of Chemical Weathering of Sedimentary Rocks. Engineering Geology, 2000, 55(1–2): 3-14.

[4]	Cripps J. C., Edwards R. L.. Hawkins A. B.. Some Geotechnical Problems Associated with Pyrite Bearing Mudrocks. Ground Chemistry Implications for Construction, 1997, Rotterdam, Netherlands: A. A. Balkema Oublishers 77 87

[5]	Donald R., Southam G.. Low Temperature Anaerobic Bacterial Diagenesis of Ferrous Monosulfide to Pyrite. Geochimca et Cosmochimica Acta, 1999, 63(13–14): 2019-2023.

[6]	Kusky T. M.. Landslides: Mass Wasting, Soil, and Mineral Hazards, 2008, New York: Facts on File 128

[7]	Lin H. J., Chen L. H.. Significance of Authigenic Microspheroid Pyrite by Scanning Electron Microscope. Science in China (Ser. B), 1983, XXVI(9): 971-980.

[8]	Ohfuji H., Akai J.. Icosahedral Domain Structure of Framboidal Pyrite. American Mineralogist, 2002, 87(1): 176-180.

[9]	Shin J.. Landslide Researcher’s Retrospection. Landslide, 1999, 36(1): 1-2.

[10]	Steward H. E., Cripps J. C.. Some Engineering Implications of Chemical Weathering of Pyritic Shale. Quarterly Journal of Engineering Geology and Hydrogeology, 1983, 16(4): 281-289.

[11]	The Japan Landslide Society Landslide in Japan, 1996 5th ed.. Tokyo, Japan: National Conference of Landslide Control 57

[12]	Toyama Prefecture, 1992. Geological Map of Toyama Prefecture (1: 100 000) and Its Explanation. 201 (in Japanese)

[13]	Wilkin R. T., Barnes H. L.. Pyrite Formation by Reactions of Iron Monosulfides with Dissolved Inorganic and Organic Sulfur Species. Geochimica et Cosmochimica Acta, 1996, 60(21): 4167-4179.

[14]	Wilkin R. T., Barnes H. L.. Pyrite Formation in an Anoxic Estuarine Basin. American Journal of Science, 1997, 297(6): 620-650.

[15]	Xu S., Zheng G. D., Lang Y. G.. Radiocarbon Dating and Mössbauer Spectroscopic Study of the Mukaiyama Landslide, Japan. Journal of Radioanalytical and Nuclear Chemistry, 2003, 258(2): 307-314.

[16]	Yang, P., Sokobiki, H., Kitagawa, R., et al., 1995. Mineralogical and Chemical Implications of Tertiary Mudstone Landslide. Proc. XX IUFRO World Congress. Tampere, Finland. 113-125

[17]	Zheng G. D., Lang Y. H., Matsuo M., . Mössbauer Spectroscopic Characterization of Iron Species in Sliding Mud. Hyperfine Interactions, 2002, 141(1–4): 361-367.

[18]	Zheng G. D., Lang Y. H., Takano B., . Iron Speciation of Sliding Mud in Toyama Prefecture, Japan. Journal of Asian Earth Sciences, 2002, 20(8): 955-963.