Geochemistry of Middle Triassic radiolarian cherts from northern Thailand: Implication for depositional environment

Hathaithip Thassanapak; Mongkol Udchachon; Chongpan Chonglakmani; Qinglai Feng

doi:10.1007/s12583-011-0220-7

Journal of Earth Science ›› 2011, Vol. 22 ›› Issue (6) : 688 -703. DOI: 10.1007/s12583-011-0220-7

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Geochemistry of Middle Triassic radiolarian cherts from northern Thailand: Implication for depositional environment

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Abstract

Geochemical analysis reveals that Middle Triassic radiolarian cherts from northern Thailand, including Chiang Dao, Lamphun and Den Chai, are of biogenic origin. These cherts present slightly high SiO₂ content which was possibly modified by diagenetic alteration and migration processes as indicated by negative correlation between SiO₂ and most of the other major elements. The relatively high content of Cr, Zr, Hf, Rb and Th and high positive correlation of these elements with Al and Ti from the majority of cherts suggest a close relation to terrigenous component. The Ce anomaly (Ce/Ce*) with geometric means ranging from 0.85 to 0.93 is compatible with that of continental margin composition (0.67–1.52) from Murray et al. (1990) which is also consistent with low Eu anomalies (Eu/Eu*, 0.91–0.94). Moreover, the slightly low ratios of La and Ce NASC normalized (La_n/Ce_n, 0.91–0.94) and the low LREE and HREE ratios in most of our samples (La_n/Yb_n, 0.62–0.85) are in agreement with the continental margin. The result from La_n/Ce_n vs. Al₂O₃/(Al₂O₃+Fe₂O₃) discrimination diagrams also supports the continental margin (residual basin, s. str.) interpretation. These geochemical results are compatible with geological evidence, which suggest that during the Middle Triassic, radiolarian cherts were deposited within a deeper part of a residual basin in which an accommodation space was possibly controlled by faults under extensional regime subsequent to Late Variscan (Permian) orogeny. Paleogeographically, the main Paleotethys which closed during Late Triassic should be located further to the west of these study localities. This scenario is in agreement with the current view of the Tethys in this part of the world.

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Triassic / geochemistry / radiolarian chert / depositional environment / northern Thailand

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Hathaithip Thassanapak, Mongkol Udchachon, Chongpan Chonglakmani, Qinglai Feng. Geochemistry of Middle Triassic radiolarian cherts from northern Thailand: Implication for depositional environment. Journal of Earth Science, 2011, 22(6): 688-703 DOI:10.1007/s12583-011-0220-7

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Adachi M., Yamamoto K., Sugisaki R.. Hydrothermal Chert and Associated Chert from the Northern Pacific, Their Geological Significance as Indication of Ocean Ridge Activity. Sedimentary Geology, 1986, 47: 125-148.

[2]	Caridroit M.. Thanasuthipitak T.. Permian Radiolarian from NW Thailand. Proceeding of International Symposium on Biostratigraphy of Mainland Southeast Asia: Facies and Paleontology, 1993, Thialand: Chiang Mai University 83 96

[3]

Chaodumrong P., Burret C., . Dheeradirok P., Hinthong C., Chaodumrong P., . Early Late Triassic Continental Colliding between Shan-Thai and Indochina Terranes as Indicated by Occurrence of Fan Delta Red Beds of Pha Daeng Formation, Central North Thailand. Proceedings of International Conference on Stratigraphy and Tectonic Evolution of Southeast Asia and the South Pacific. Geological Survey Division, 1997, Bangkok, Thailand: Department of Mineral Resources 143 157

[4]	Charoenprawat A., Chuaviroj S., Hinthong C., . Geologic Map of Changwat Lampang, Scale 1: 250 000, 1994, Bangkok, Thailand: Department of Mineral Resources

[5]	Chen D. Z., Qing H. R., Yan X., . Hydrothermal Venting and Basin Evolution (Devonian, South China): Constraints from Rare Earth Element Geochemistry of Chert. Sedimentary Geology, 2006, 183(3–4): 203-216.

[6]	Chonglakmani, C., 1999. The Triassic System of Thailand: Implications for the Paleogeography of Southeast Asia. In: Rattanasatein, B., ed., Proceeding of International Symposium on Shallow Tethys (ST) 5. Department of Geological Sciences, Chiang Mai University. 486–495

[7]	Chonglakmani C.. Current Status of Triassic Stratigraphy of Thailand and Its Implication for Geotectonic Evolution. Proc. Symp. Geology of Thailand, 2002, Bangkok, Thailand: Department of Mineral Resources 1 3

[8]	Chonglakmani C., Grant-Mackie J. A.. Thanasuthipitak T.. Biostratigraphy and Facies Variation of the Marine Triassic Sequences in Thailand. Proceeding of the International Symposium on Biostratigraphy of Mainland Southeast Asia: Facies and Paleontology, 1993, Thailand: Chiang Mai University 97 123

[9]	Feng, Q. L., Chonglakmani, C., Helmcke, D., et al., 2002. Middle Triassic Radiolarian Fauna from Lumphun, Northern Thailand. In: Proceeding of the International Symposium on Geology of Thailand. Bangkok, Thailand. 26–31

[10]	Feng Q. L., Chonglakmani C., Helmcke D., . Correlation of Triassic Stratigrasphy between the Simao and Lampang-Phrae Basins: Implication for the Tectonopaleography of Southeast Asia. Journal of Asian Earth Sciences, 2005, 24: 777-785.

[11]	Feng Q. L., Malila K., Wonganan N., . Permian and Triassic Radiolaria from Northwest Thailand: Palaeogeographical Implications. Revue de Micropaleontologie, 2005, 48(4): 237-255.

[12]	Ferrari O. M., Hochard C., Stampfli G. M.. An Alternative Plate Tectonic Model for the Palaeozoic-Early Mesozoic Palaeotethyan Evolution of Southeast Asia (Northern Thailand-Burma). Tectonophysics, 2008, 451: 346-365.

[13]	Geological Survey Division Geological Map of Thailand, Scale 1: 2500 000, 1999, Bangkok, Thailand: Department of Mineral Resources

[14]	German C. R., Klinkhammer G. P., Edmond J. M., . Hydrothermal Scavenging of Rare-Earth Elements in the Ocean. Nature, 1990, 345: 516-518.

[15]	Gromet L. P., Dymek R. F., Haskin L. A., . The “North American Shale Composite”: Its Compilation, Major and Trace Element Characteristics. Geochim. Cosmochim. Acta, 1984, 48(12): 2469-2482.

[16]	Halamić J., Marchig V., Goričan S.. Geochemistry of Triassic Radiolarian Cherts in North-Western Croatia. Geologica Carpathica, 2001, 52(6): 327-342.

[17]	Helmcke D.. The Permo-Triassic Paleotethys in Mainland Southeast-Asia and Adjacent Parts of China. Geologische Rundschau, 1985, 74(2): 215-228.

[18]	Helmcke, D., 1994. Distribution of Permian and Triassic Syn-Orogenic Sediments in Central Mainland SE-Asia. In: Angsuwathana, P., Wongwanich, T., Tansathien, W., et al., eds., Proceeding of the International Symposium on Stratigraphic Correlation of Southeast Asia. Bangkok, Thailand. 123–128

[19]	Hess A., Koch K. E.. Geologic Map of Northern Thailand, Scale 1: 250 000, Sheet 4 (Chiang Dao), 1979, Germany: Federal Institute for Geosciences and Natural Resources

[20]	Jaeger H., Stein V., Wolfart R.. Fauna (Graptolithen Brachiopoden) der Unterdevonischen Schwarzschiefer Nord-Thailands. Neues Jahrbuch für Geologie und Paläontologie. Abhandlungen, 1969, 133: 171-190.

[21]	Kamata Y., Sashida K., Ueno K., . Triassic Radiolarian Faunas from the Mae Sariang Area, Northern Thailand and Their Paleogeographic Significance. Journal of Asian Earth Sciences, 2002, 20: 491-506.

[22]	Kametaka M., Takebe M., Nagai H., . Sedimentary Environments of the Middle Permian Phosphorite-Chert Complex from the Northeastern Yangtze Platform, China, the Gufeng Formation: A Continental Shelf Radiolarian Chert. Sedimentary Geology, 2005, 174(3/4): 197-222.

[23]	Marchig V., Gundlach H., Möller P., . Some Geochemical Indicators for Discrimination between Diagenetic and Hydrothermal Metalliferous Sediments. Marine Geology, 1982, 50(3): 241-256.

[24]	Meesook A., Suteethon V., Chaodumrong P., . Montajit N., Potisat S., Wongwanich T., . Mesozoic Rocks of Thailand: A Summary. Proceedings of the Symposium on Geology of Thailand, 2002, Bangkok, Thailand: Department of Mineral Resources 82 94

[25]	Murray R. W.. Chemical Criteria to Identify the Depositional Environment of Chert: General Principles and Applications. Sedimentary Geology, 1994, 90: 213-232.

[26]	Murray R. W., Buchholtz ten Brink M. R., Gerlach D. C., . Rare Earth Elements as Indicators of Different Marine Depositional Environments in Chert and Shale. Geology, 1990, 18(3): 268-271.

[27]	Murray R. W., Buchholtz ten Brink M. R., Gerlach D. C., . Rare Earth, Major, and Trace Elements in Chert from the Franciscan Complex and Monterey Group, Californian: Assessing REE Sources to Fine-Grained Marine Sediments. Geochim. Cosmochim. Acta, 1991, 55(7): 1875-1895.

[28]	Rangin C., Steinberg M., Bonnot-Courtois C.. Geochemistry of the Mesozoic Bedded Chert of Central Baja California (Vizcaino-Cedros-San Benito): Implication for Palaogeographic Reconstruction of an Old Oceanic Basin. Earth and Planetary Science Letter, 1981, 54: 313-322.

[29]	Sashida K., Igo H., Hisada K., . Occurrence of Paleozoic and Early Mesozoic Radiolarian in Thailand (Preliminary Report). Journal of Southeast Asian Earth Sciences, 1993, 8: 97-108.

[30]	Taylor S. R., McLennan S. M.. The Continental Crustal: Its Composition and Evolution, 1985, Oxford: Blackwell

[31]

Thassanapak, H., Chonglakmani, C., Feng, Q. L., et al., 2007. Middle Triassic Radiolarians from Den Chai Area, Northern Thailand. In: Tantiwanit, W., Raksasakulwong, L., Suteethorn, V., et al., eds., Proceeding of the International Conference on Geology of Thailand: Towards Sustainable Development and Sufficiency Economy. Bankkok, Thailand. 180–186

[32]	Thassanapak H., Feng Q. L., Grant-Mackie J., . Middle Triassic radiolarian faunas from Chiang Dao, Northern Thailand. Palaeoworld, 2011, 20(2–3): 179-202.

[33]	Ueno K.. The Permian Fusulinoidean Faunas of the Sibumasu and Baoshan Blocks: Their Implication for the Paleogeographic and Paleoclimatologic Reconstruction of the Cimmerian Continent. Palaeogeography, Palaeoclimatology, Paleoecology, 2003, 193(1): 1-24.

[34]	Wang X. D., Ueno K., Mizuno Y., . Late Paleozoic Faunal, Climatic, and Geographic Changes in the Baochan Block as a Gondwana-Derived Continental Fragment in Southwest China. Palaeogeography, Palaeoclimatology, Palaeoecology, 2001, 170: 197-218.

[35]	Yamamoto K.. Geochemical Characteristics and Depositional Environments of Cherts in the Franciscan and Shimanto Terranes. Sedimentary Geology, 1987, 52(1–2): 65-108.