Milankovitch-driven cycles in the Precambrian of China: The Wumishan Formation
Mei Mingxiang1,*, Maurice E. Tucker2
1. State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences (Beijing), Beijing 100083, China
2. Department of Earth Sciences, University of Durham, Durham DH1 3LE, UK
Carbonate strata of the Mesoproterozoic Wumishan Formation in the Jixian area near Tianjin are ~3300 m thick and were deposited over some 100 million years (from ~1310±20 Ma to ~1207±10 Ma). Metre-scale cycles (parasequences) dominate the succession. They are generally of the peritidal carbonate type, and mostly show an approximately symmetrical lithofacies succession with thick stromatolite biostromes and small thromboliteoncolite bioherms constituting the central part and tidal-flat dolomites forming the upper and lower parts. Lagoonal-supratidal dolomitic shales with palaeosol caps make up the topmost layers. The boundaries of the Wumishan cycles are typically exposure surfaces, and there is abundant evidence for fresh-water diagenesis. Widespread 1:4 stacking patterns indicate that the individual Wumishan cycles are sixthorder parasequences, with 4 parasequences constituting one fifth-order parasequence set. Locally, 5-8 beds or couplets, can be discerned in some of the cycles. The regular vertical stacking pattern of beds within the sixth-order parasequences, forming the fifth-order parasequence sets, are interpreted as the result of environmental fluctuations controlled by Milankovitch rhythms, namely the superimposition of precession, and short and long-eccentricity. The widespread 1:4 stacking pattern in the cyclic succession, as well as the local 1:5-8 stacking patterns of the beds within the cycles, suggest that the Milankovitch rhythms had similar ratios in the Mesoproterozoic as in the Phanerozoic. Based on the cycle stacking patterns, 26 thirdorder sequences can be distinguished and these group into 6 second-order, transgressiveregressive megasequences (or sequence sets), all reflecting a composite, hierarchical succession of relative sea-level changes.
Mei Mingxiang,Maurice E. Tucker. Milankovitch-driven cycles in the Precambrian of China: The Wumishan Formation[J]. Journal of Palaeogeography, 2013, 2(4): 369-389.
Mei Mingxiang,Maurice E. Tucker. Milankovitch-driven cycles in the Precambrian of China: The Wumishan Formation[J]. Journal of Palaeogeography, 2013, 2(4): 369-389.
Aitken, J. D., Narbonne, G. M., 1989. Two occurrences of Precambrian thrombolites from the Mackenzie Mountains, northwestern Canada. Palaios, 4: 384-388.
Anderson, E. J., Goodwin, P. W., 1989. The significance of metrescale allocycles in the quest for a fundamental stratigraphic unit. Journal of Geological Society of London, 147: 507-518.
Banerjee, S., 2000. Climatic versus tectonic control on storm cyclicity in Mesoproterozoic Koldaha Shale, central India. Gondwana Research, 3: 521-528.
Banerjee, S., Bhattacharya, S. K., Sarkar, S., 2007. Carbon and oxygen isotopic variations in peritidal stromatolite cycles, Paleoproterozoic Kajrahat Limestone, Vindhyan basin of central India. Journal of Asian Earth Sciences, 29: 823-831.
Berger, A., Loutre, M. F., Laskar, J., 1992. Stability of the astronomical frequencies over the Earth��s history for palaeoclimate studies. Science, 255: 560-566.
Blendinger, W., 2004. Sea-level changes versus hydrothermal diagenesis: origin of Triassic carbonate platform cycles in the Dolomites, Italy. Sedimentary Geology, 169: 21-28.
Brett, C. E., Allison, P. A., Tsujita, C. J., Soldani, D., Moffat, H. A., 2006. Sedimentology, taphonomy, and paleoecology of meterscale cycles from the upper Ordovician of Ontario. Palaios, 21: 530-547.
Brett, C. E., Goodman, M. W., LoDoca, S. T., 1990. Sequences, cycles and basin dynamics in the Silurian of the Appalachian foreland basin. Sedimentary Geology, 69: 191-224.
Burgess, P. M., 2001. Modeling carbonate sequence development without sea-level oscillation. Geology, 29: 1127-1130.
2.0.CO;2 target="_blank">
Burgess, P. M., 2006. The signal and the noise: Forward modeling of allocyclic and autocyclic processes influencing peritidal carbonate stacking patterns. Journal of Sedimentary Research, 76: 962-977.
Burgess, P. M., Wright, V. P., Emery, D., 2001. Numerical forward modeling of peritidal carbonate parasequence development: implication for outcrop interpretation. Basin Research, 13: 1-17.
Catuneanu, O., Martins-Neto, M. A., Eriksson, P. G., 2005. Precambrian sequence stratigraphy. Sedimentary Geology, 176: 67-95.
Catuneanu, O., Zecchin, M., 2013. High-resolution sequence stratigraphy of clastic shelves II: Controls on sequence development. Marine and Petroleum Geology, 39: 26-38.
Chen, D., Tucker, M. E., 2003. The Frasnian-Famennian mass extinction: insights from high-resolution sequence stratigraphy and cyclostratigraphy in South China. Palaeogeography, Palaeoclimatology, Palaeoecology, 183: 1-25.
Cozzi, A., Hinnov, L. A., Hardie, L. A., 2005. Orbitally-forced Lofer cycles in the Dachstein Limestone of the Julian Alps (northeastern Italy). Geology, 33: 789-792.
D��Argenio, B., Ferreri, V., Amodio, S., Pelosi, N., 1997, Hierarchy of high-frequency orbital cycles in Cretaceous carbonate platform strata. Sedimentary Geology, 113: 169-193.
de Boer, P. L., Smith, D. G., 1994. Orbital forcing and cyclic sequences. In: de Boer, P. L., Smith, D. G., (eds). Orbital Forcing and Cyclic Sequences. Special Publication of International Association of Sedimentologists, 19: 1-14.
Drummond, C. N., Wilkinson, B. H., 1993. On the use of cycle thickness diagrams as records of long-term sea-level changes during accumulation of carbonate sequences. Journal of Geology, 101: 139-182.
Du Rulin, 1992. Earth History and Palaeontology in the Precambrian. Beijing: Geological Publishing House, 68-138 (in Chinese).
Einsele, G., Ricken, W., Seilacher, A., 1991. Cycles and Events in Stratigraphy. New York: Springer-Verlag.
Eriksson P. G., Catuneanu, O., Sarkar, S., Tirsgaard, H., 2005a. Patterns of sedimentation in the Precambrian. Sedimentary Geology, 176: 17-42.
Eriksson P. G., Catuneanu, O., Nelson, D. R., Popa, M., 2005b. Controls on Precambrian sea-level change and sedimentary cyclicity. Sedimentary Geology, 176: 43-65.
Ettensohn, F. R., Zhang, C., Gao, L., Lierman, R. T., 2011. Softsediment deformation in epicontinental carbonates as evidence of paleoseismicity with evidence for a possible new seismogenic indicator: Accordion folds. Sedimentary Geology, 235: 222-233.
Fischer, A. G., Bottjer, D. J., 1991. Orbital forcing and sedimentary sequences. Journal of Sedimentary Petrology, 61: 1063-1069.
Gao Linzhi, Zhang Yuxu, Wang Chengshu, Peng Yang, 1996. Preliminary study on the sequence stratigraphy of the middle and upper Proterozoic in Jixian near Tianjin. Regional Geology of China 56, 64-74 (in Chinese with English abstract).
Goldhammer, R. K., Dunn, P. A., Hardie, L. A., 1990. Depositional cycles, composite sea-level changes, cycle stacking patterns, and the hierarchy of stratigraphic forcing: example from Alpine Triassic platform carbonates. Geological Society of American Bulletin, 102: 535-562.
2.3.CO;2 target="_blank">
Gebelein, C. D., 1974. Biological control of stromatolite microstructure: implication for Precambrian time stratigraphy. American Journal of Science, 274: 575-598.
Grotzinger, J. P., James, N. P., 2000. Precambrian carbonates: evolution of understanding. In: Grotzinger, J. P., James N. P., (eds). Carbonate Sedimentation and Diagenesis in the Evolving Precambrian World. SEPM Special Publication, 67: 3-22.
Helle, S. K., 2004. Sequence stratigraphy in a marine moraine at the head of Hardangerfjorden, western Norway: evidence for a highfrequency relative sea-level cycle. Sedimentary Geology, 164: 251-281.
Hinnov, L. A., 2000. Invited: New perspectives on orbitally-forced stratigraphy. Annual Review of Earth and Planetary Sciences, 28: 419-475.
Huang Xueguang, He Yuzhen, Wang Yalie, 1996. Sepiolite Deposits in North China: Their Occurrence, Genesis and Use. Beijing: Geological Publishing House, 5-45 (in Chinese).
Kennard, J. M., James, N. P., 1986. Thrombolites and stromatolites: Two distinct types of microbial structure. Palaios, 1: 492-503.
Knoll, A. H., Semikhatov, M. A., 1998. The genesis and time distribution of two distinctive Proterozoic stromatolite microstructures. Palaios, 13: 408-422.
Koerschner, W. F., Read J. F., 1989. Field and modeling studies of Cambrian carbonate cycles, Virginian Appalachians. Journal of Sedimentary Petrology, 59: 654-687.
Liang Yuzuo, Cao Ruiji, Zhang Luyi, 1984. Pseudogymnsolenaceae of the upper Precambrian. Beijing: Geological Publishing House, 198 (in Chinese).
Mei Mingxiang, Xu Debing, Zhou Hongrui, 2000a. Genetic types of meter-scale sequence and the nature of their facies succession. Journal of China University of Geosciences, 11: 375-382.
Mei Mingxiang, Zhou Hongrui, Du Benming, Luo Zhiqing, 2000b. Meso- and Neoproterozoic sedimentary sequences in Jixian, Tianjin, Northern China: Division of the first-order sequences of the Precambrian strata (1800Ma-600Ma) and their comparison with Phanerozoic strata. Sedimentary and Tethyan Geology, 20(2): 48-59 (in Chinese with English abstract).
Mei Mingxiang, Li Zhizhong, Bai Zhida, Xu Debing, 1998a. Preliminary study of the middle and upper Proterozoic cyclic sequences in Xinglong County, Hebei Province. Journal of Stratigraphy, 22: 102-108 (in Chinese with English abstract).
Mei Mingxiang, Li Zhizhong, Xu Debing, 1998b. Composite cyclicsequences in the Wumishan Formation of Mesoproterozoic age in Xinglong county, Hebei Province. Geosciences, 12 (suppl.): 48-55 (in Chinese with English abstract).
Mei Mingxiang, Bai Zhida, Xu Debing, 1998c. Cyclic-sequences and stratigraphic framework of the Tushanzi Formation of Meso- Proterozoic age, Xinglong County, Hebei Province. Journal of Guilin Institute of Technology, 18(3): 40-44 (in Chinese with English abstract).
Mei Mingxiang, Xu Debing, Sun Kaisun, 1998d. Carbonate cyclicsequences due to composite sea-level changes, Gaoyuzhuang Formation of Meso-Proterozoic age, Xinglong County, Hebei Province. Geosciences, 12 (Suppl.): 30-39 (in Chinese with English abstract).
Mei Mingxiang, Mei Shilong, 1997. Cyclic-sequences due to composite sea-level changes developed in the Middle Cambrian Zhangxia Formation, North-China. Acta Sedimentologica Sinica, 15: 5-10 (in Chinese with English abstract).
Mei Mingxiang, Ma Yongsheng, Zhou Peikang, Su Dechen, Luo Guangwen, 1997. Introduction to Carbonate Sedimentology. Beijing: Seismological Publishing House, 301 (in Chinese).
Mei Mingxiang, Xu Deibing, 1996. Problems of cyclic records in sedimentary strata - Discussion of working methods of outcrop sequence stratigraphy. Geosciences, 10: 85-92 (in Chinese with English abstract).
Mei Mingxiang, 1996. Discussing complexity in lithostratigraphy and the stratigraphic record. Journal of Stratigraphy, 20: 207- 212 (in Chinese with English abstract).
Mei Mingxiang, 1995. Carbonate Cycles and Sequences. Guiyang: Guizhou Sciences and Technology Publishing House, 245 (in Chinese).
Mei Mingxiang, 1993. Genetic types of carbonate metre-scale cyclicsequences and their discerning marks. Sedimentary Facies and Palaeogeography, 13: 34-45 (in Chinese with English abstract).
Miall, A. D., 1990. Stratigraphic sequences and their chronostratigraphic correlation. Journal of Sedimentary Petrology, 61: 497- 505.
Miall, A. D., 2005. Testing for eustatic sea-level control in the Precambrian sedimentary record. Sedimentary Geology, 176: 9-16.
Montanez, I. P., Osleger, D. A., 1993. Parasequence stacking patterns, third-order accommodation events and sequence stratigraphy of Middle to Upper Cambrian platform carbonates, Bonanza King Formation, southern Great Basin. In: Loucks, R. G., Sarg, J. F., (eds). Recent Advances and Applications of Carbonate Sequence Stratigraphy. AAPG Memoir, 57: 305-321.
Mullar, R. A., MacDonald G. J., 1995. Global cycles and orbital inclination. Nature, 377: 107-108.
Osleger, D. A., Read J. F., 1991. Relation of eustasy to stacking patterns of meter-scale carbonate cycles, Late Cambrian, USA. Journal of Sedimentary Petrology, 61: 1225-1552.
Pepper, T., Cloetingh, S., 1995. An autocyclic perturbation of orbitally- forced signals in the sedimentary record. Geology, 23: 937- 940.
2.3.CO;2 target="_blank">
Poletti, L., Silva, I. P., Masetti, D., Pipan, M., Claps, M., 2004. Orbitally- driven fertility cycles in the Palaeocene pelagic sequences of the Southern Alps (Northern Italy). Sedimentary Geology, 164: 35-54.
Qiao Xiufu, Li Haibing, 2009. Effect of earthquake and ancient earthquake on sediments. Journal of Paleogeography, 11: 593- 610 (in Chinese with English abstract).
Read, J. F., Goldhammer R. K., 1988. Use of Fischer plots to define third-order sea-level curves in Ordovician peritidal cyclic carbonates, Appalachians. Geology, 16: 895-899.
2.3.CO;2 target="_blank">
Read, J. F., 1995. Overview of carbonate platform sequences, cycle stratigraphy and reservoirs in greenhouse and icehouse worlds.
In: Read, J. F., (ed). Milankovitch Sea-level Changes, Cycles and Reservoirs on Carbonate Platforms in Greenhouse and Icehouse Worlds. SEPM Short Course Notes, 35: 102.
Riding, R., 2000. Microbial carbonates: the geological record of calcified bacterial-algal mats and biofilms. Sedimentology, 47: 179-214.
Schwarzacher, W., 1993. Milankovitch theory and cyclostratigraphy. Amsterdam: Elsevier, 368.
Schwarzacher, W., 2005. The stratification and cyclicity of the Dachstein Limestone in Lofer, Leogang and Steinernes Meer (Northern Calcareous Alps, Austria). Sedimentary Geology, 181: 93-106.
Song Tianrui, Zhao Zhen, Wang Changyao, 1991. Beijing: Proterozoic Sedimentary Rocks in North-China. Beijing Sciences and Technology Publishing House, 193 (in Chinese).
Spence, G. H., Tucker, M. A., 2007. A proposed integrated multisignature model for peritidal cycles in carbonates. Journal of Sedimentary Research, 77: 797-808.
Su Dechen, Sun Aiping, 2012. Typical earthquake-induced soft-sediment deformation structures in the Mesoproterozoic Wumishan Formation, Yongding River Valley, China and interpreted earthquake frequency. Journal of Palaeogeography, 1(1): 71-89.
Tipper, J. C., 2000. Patterns of stratigraphic cyclicity. Journal of Sedimentary Research, 70: 1262-1279.
Tucker, M. E., Wright, V. P., 1990. Carbonate Sedimentology. Oxford: Blackwell Scientific Publication, 482.
Tucker, M. E., 1993. Carbonate diagenesis and sequence stratigraphy. Oxford: Sedimentology Review, 1. Blackwell Scientific Publication: 51-72.
Tucker, M. E., Garland, J., 2010. High-frequency cycles and their sequence stratigraphic context: orbital forcing and tectonic controls on Devonian cyclicity, Belgium. Geologica Belgica, 13 (3): 213-240.
Vail, P. R., Mitchum, R. M., Thompson, S., 1977. Seismic stratigraphy and global changes of sea level, part 3 and part 4. AAPG Memoir, 26: 63-98.
Van der Zwan, C. J., 2002. The impact of Milankovitch-scale climatic forcing on sediment supply. Sedimentary Geology, 147: 271-294.
Wang Songshan, Shang Haiqing, Qiu Yi, Chen Menge, 1995. Determination of the ages of the Yangzhuang and Wumishan Formations, Jixian section. Scientia Geological Sinica, 30: 166-172 (in Chinese with English abstract).
Wilkinson, B. H., Diedrich, N. W., Drummond, C.N., 1996. Facies succession in peritidal carbonate sequences. Journal of Sedimentary Research, 66: 1065-1078.
Xing Yusheng, Gao Zhenxi, Liu Guizhi, Qiao Xiufu, 1989. The Upper Precambrian in China. Beijing: Geological Publishing House, 316 (in Chinese).
Zecchin, M., 2007. The architectural variability of small-scale cycles in shelf and ramp clastic systems: the controlling factors. Earth- Science Reviews, 84: 21-55.
Zecchin, M., 2010. Towards the standardization of sequence stratigraphy: is the parasequence concept to be redefined or abandoned? Earth-Science Reviews, 102: 117-119.
Zecchin, M., Catuneanu, O., 2013. High-resolution sequence stratigraphy of clastic shelves I: Units and bounding surfaces. Marine and Petroleum Geology, 39: 1-25.
Zhao Zhen, 1988. A sedimentary model for tidal flats of epicontinental seas. Acta Sedimentologica Sinica, 6 (2): 68-76 (in Chinese with English abstract).
Zhao Zhen, 1992. Dispersal grain: The embryonic form of oncolite. Acta Sedimentologica Sinica, 10(2): 19-27 (in Chinese with English abstract).
Zhu Shixing, Liang Yuzuo, Du Rulin, Chen Jinbiao, 1993. Stromatolites. Tianjin: China Publishing House of Tianjin University, 193 (in Chinese).
Zhu Shixing, Xing Yusheng, Zhang Pengyuan, 1994. Biostratigraphic Sequences of the Middle-Upper Proterozoic on the North- China Platform. Beijing: Geological Publishing House, 278 (in Chinese).
Z��hlke, R., Bechst?dt, T., Mundil, R., 2003. Sub-Milankovitch and Milankovitch forcing on a model Mesozoic carbonate platform�� The Latemar (Middle Triassic, Italy). Terra Nova, 15: 69-80.
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