| Citation: | Mingxiang Mei. Implications of the Precambrian Non-stromatolitic Carbonate Succession Making up the Third Member of Mesoproterozoic Gaoyuzhuang Formation in Yanshan Area of North China. Journal of Earth Science, 2007, 18(3): 191-209.
|
A particular non-stromatolitic carbonate succession making up the third member of the Mesoproterozoic Gaoyuzhuang (高于庄) Formation might demonstrate that a stromatolite decline of the Mesoproterozoic occurring at ca. 1 450 Ma besides other three events of the Proterozoic, respectively, occurred at ca. 2 000 Ma, ca. 1 000 Ma, and ca. 675 Ma. The forming duration of this non-stromatolitic carbonate succession can be generally correlative to that of a similar depositional succession in North America, i.e. a non-stromatolitic carbonate succession made up by the Helena Formation of the Belt Supergroup, which suggests that the stromatolite decline occurring at ca. 1 450 Ma may be a global event. This information endows the non-stromatolitic carbonate succession making up the third member of the Gaoyuzhuang Formation in the Yanshan (燕山) area with important significance for the further understanding of Precambrian sedimentology. The Mesoproterozoic Gaoyuzhuang Formation in Yanshan area is a set of more than 1 000 m thick carbonate strata that can be divided into four members (or subformations). The first member (or the Guandi (官地) subformation) is marked by a set of stromatolitic dolomites overlying a set of transgressive sandstones; the second member (or the Sangshu’an (桑树鞍) subformation) is a set of manganese dolomites with a few stromatolites; the third member (or the Zhangjiayu (张家峪) subformation) is chiefly made up of leiolite and laminite limestones and is characterized by the development of molar-tooth structures in leiolite limestone; the fourth member (or the Huanxiusi (环秀寺) subformation) is composed of a set of dolomites of stromatolitic reefs or lithoherms. Sequence-stratigraphic divisions at two sections, i.e. the Jixian (蓟县) Section in Tianjin (天津) and the Qiangou (千沟) Section of Yanqing (延庆) County in Beijing (北京), demonstrate that a particularly non-stromatolitic succession making up the third member of the Mesoproterozoic Gaoyuzhuang Formation is developed in the Yanshan area of North China, in which lots of grotesque matground structures (wrinkle structures and palimpsest ripples) are developed in beds of leiolite limestone at the Qiangou Section and lots of molar-tooth structures are developed in beds of leiolite limestone at the Jixian Section. The time scale of the Gaoyuzhuang Formation is deduced as 200 Ma (from 1 600 Ma to 1 400 Ma). The duration of an obvious hiatus between the Gaoyuzhuang Formation and the underlying Dahongyu (大红 峪) Formation is deduced as 50 Ma to 100 Ma, thus the forming duration of the Gaoyuzhuang Formation is thought as 100 Ma (1 500 Ma to 1 400 Ma). Furthermore, the age of the subface of the third member of the Gaoyuzhuang Formation that is just in the mid position of the Gaoyuzhuang Formation can be deduced as about 1 450 Ma, which is the basis to infer a stromatolite decline of the Mesoproterozoic occurring at ca. 1 450 Ma. Importantly, several features of both the molar-tooth structure and the stromatolite, such as the particular forming environment, the important facies-indicative meaning, and the episodic distribution in the earth history, might express the evolutionary periodicity of the surface environment of the earth and can provide meaningful clues for the understanding of the Precambrian world, although their origin and forming mechanism is highly contentious. Therefore, like other three stromatolitic declines, respectively, occurring at ca. 675 Ma, ca. 1 000 Ma, and ca. 2 000 Ma, the identification of the stromatolite decline occurring at ca. 1 450 Ma during the Golden Age of stromatolites (2 800 Ma to 1 000 Ma) has important meaning for the further understanding of the evolving carbonate world of the Precambrian.
| Awramik, S. M., 1971. Precambrian Columnar Stromatolite Diversity: Reflection of Metazoan Appearance. Science, 174: 825–827 doi: 10.1126/science.174.4011.825 |
| Awramik, S. M., Schopf, J. W., Walter, M. A., 1983. Filamentous Fossil Bacteria from the Archean of Western Australia. Precambrian Research, 20: 357–374 doi: 10.1016/0301-9268(83)90081-5 |
| Bishop, J. W., Sumner, D. Y., 2006. Molar Tooth Structures of the Neoarchean Montevielle Formation, Transvaal Supergroup, South Africa, Ⅰ: Constraints on Microcrystalline CaCO3 Precipitation. Sedimentology, 53(5): 1049–1068 doi: 10.1111/j.1365-3091.2006.00801.x |
| Bishop, J. W., Sumner, D. Y., Huerta, N. J., 2006. Molar Tooth Structures of the Neoarchean Montevielle Formation, Transvaal Supergroup, South Africa, Ⅱ: A Wave-Induced Fluid Flow Model. Sedimentology, 53(5): 1069–1082 doi: 10.1111/j.1365-3091.2006.00802.x |
| Bowring, S. A., Grotzeinger, J. P., Isachsen, C. E., et al., 1993. Calibrating Rates of Early Cambrian Evolution. Science, 261: 203–223 doi: 10.1126/science.8327891 |
| Braga, J. C., Martin, J. M., Riding, R., 1995. Controls on Microbial Dome Fabric Development along a Carbonate-Siliciclastic Shelf-Basin Transect, Miocene, S.E. of Spain. Palaios, 10: 347–361 doi: 10.2307/3515160 |
| Brocks, J. J., Logan, G. A., Buick, R., et al., 1999. Archean Molecular Fossils and the Early Rise of Eukaryotes. Science, 285: 1033–1036 doi: 10.1126/science.285.5430.1033 |
| Campbell, F. H. A., Cecile, M. P., 1976. Geology of the Kilohigok Basin, Bathurst Inlet, District of Mackenzie. Geological Survey of Canada Papers, 76: 369–377 |
| Chen, J. B., Wu, T. S., 1997. Regional Stratigraphy in North China. China University of Geosciences Press, Wuhan. 20–44 (in Chinese) |
| Du, R. L., 1992. Earth History and Paleontology in Precambrian. Geological Publishing House, Beijing. 1–239 (in Chinese) |
| Fagerstrom, J. A., 1987. The Evolution of Reef Communities. John and Sons, New York. 1–449 |
| Fang, Z. J., 2004. Major Bio-events in Permian–Triassic Reef Ecosystem of South China and Their Bearing on Extinction-Survey-Recovery Problems. In: Rong, J. Y., Fang, Z. J., eds., Mass Extinction—Evidence from the Palaeozoic and Triassic of South China. University of Science and Technology of China Press, Hefei. 475–542 (in Chinese) |
| Fischer, A. G., 1965. Fossils Early Life and Atmospheric History. Proc. Nat. Acad. Sci. , 53: 1205–1215 |
| Furniss, G., Rittle, J. F., Winston, D., 1998. Gas Bubble and Expansion Crack Origin of "MT" Structure from the Late Precambrian Belt Purcell Supergroup. Journal of Sedimentary Research, 68: 104–114 doi: 10.2110/jsr.68.104 |
| Gao, L. Z., Zhang, Y. X., Wang, C. X., et al., 1996. Preliminary Study on Sequence Stratigraphy of the Middle and Upper Proterozoic in Jixian of Tianjin. Regional Geology of China, 56: 64–74 (in Chinese with English Abstract) |
| Ge, M., Meng, X. H., Kuang, H. W., et al., 2003. Microspar Molar-Tooth Carbonate: New Hotspot on Global Studies of Sedimentology in 21st Century. Acta Sedimentologica Sinica, 21(1): 81–89 (in Chinese with English Abstract) |
| Gingras, M. K., 2002. Microbially Induced Sedimentary Structures—A New Category within the Classification of Primary Sedimentary Structures—Discussion. Journal of Sedimentary Research, 72(4): 587–588 doi: 10.1306/101401720587 |
| Grotzeinger, J. P., 1986. Shallowing-Upward Cycles of the Wallace Formation, Belt Supergroup, Northern Montana and Idaho. In: Robert, S. M., ed., Belt Supergroup: A Guide to Proterozoic Rocks of Western Montana and Adjacent Areas. Montana Bureau of Mines and Geology Spiecial Pubilication, 94: 143–160 |
| Grotzeinger, J. P., 1990. Geochemical Model for Proterozoic Stromatolite Decline. American Journal of Science, 190-A: 80–103 |
| Grotzeinger, J. P., Rothman, D. R., 1996. An Biotobic Model for Stromatolite Morphogenesis. Nature, 383: 423–425 doi: 10.1038/383423a0 |
| Grotzeinger, J. P., James, N. P., 2000. Precambrian Carbonates: Evolution of Understanding. In: Grotzeinger, J. P., James, N. P., eds., Carbonate Sedimentation and Diagenesis in the Evolving Precambrian World. SEPM Special Publication, 67: 3–22 |
| Harland, W. B., Armstrong, R. L., Cox, A. V., et al., 1990. A Geological Time Scale. Cambridge University Press, Cambridge. 1–649 |
| Hofmann, H. J., Aitken, J. D., 1979. Precambrian Biota from the Little Dal Group, Mackenzie Mountains, Northwestern Canada. Canadian Journal of Earth Sciences, 16(1): 150–166 doi: 10.1139/e79-014 |
| Hofman, H. J., 2000. Archean Stromatolites as Microbial Archives. In: Riding, R., Awramik, S. M., eds., Microbial Carbonates. Springer-Verlag, Heidelberg. 315–327 |
| James, N. P., Narbonne, G. M., Sherman, A. G., 1998. MT Carbonates: Shallow Subtidal Facies of the Mid to Late Proterozoic. Journal of Sedimentary Research, 68: 716–722 doi: 10.2110/jsr.68.716 |
| Kuang, H. W., Meng, X. H., Ge, M., 2006. Disscussion on Origin for Molar Tooth Carbonate Rocks: An Example from the Neoproterozoic in Jilin-Liaoning Area. Journal of Palaeogeography, 8(2): 63–74 (in Chinese with English Abstract) |
| Liu, P. J., 2001. Seismite and Its Rhythm in the Gaoyuzhuang Formation of Mesoproterozoic in Pingquan County, Hebei Province. Geoscience, 15(3): 266–268 (in Chinese with English Abstract) |
| Lowe, D. R., 1980. Stromatolites 3, 400–3, 500 Myr Old from the Archean of Western Australia. Nature, 284: 441–443 doi: 10.1038/284441a0 |
| Mei, M. X., 1995. Carbonate Cycles and Sequence. Guizhou Science and Technology Press, Guiyang. 1–245 (in Chinese) |
| Mei, M. X., 1998. Genetic Types of Shallow Marine Clastics and Their Stacking Patterns in Long Term Cyclic Sequences. Seimentary Facies and Paleogeography, 18(5): 64–70 (in Chinese with English Abstract) |
| Mei, M. X., 2005. Preliminary Study on Sequence-Stratigraphic Position and Origin for the Molar-Tooth Structure of the Gaoyuzhuang Formation of Mesoproterozoic at Jixian Section in Tianjin. Journal of Palaeogeography, 7(4): 437–447 (in Chinese with English Abstract) |
| Mei, M. X., 2006. Origin of Molar-Tooth Structure Based on Sequence-Stratigraphic Position and Macroscopic Features: Example from Mesoproterozoic Gaoyuzhuang Formation at Jixian Section, Tianjin, North China. Journal of China University of Geosciences, 17(3): 201–208 doi: 10.1016/S1002-0705(06)60029-0 |
| Mei, M. X., Gao, J. H., Meng, Q. F., 2006. From the Matground Structure to the Primary Sedimentary Structure of a Fifth Category: Significant Concepts on Sedimentology. Geoscience, 20(3): 413–422 (in Chinese with English Abstract) |
| Mei, M. X., Li, Z. Z., Xu, D. B., 1998a. Cyclic Sequences of Composite Sea-Level Changes of the Mesoproterozoic Wumishan Formation in Xinglong County of Hebei Province. Geoscience, 12(Suppl. ): 48–55 (in Chinese with English Abstract) |
| Mei, M. X., Xu, D. B., Sun, K. S., 1998b. Carbonate Cyclic Sequences of Composite Sea-Level Changes of Mesoproterozoic Gaoyuzhuang Formation in Xinglong County of Hebei Province. Geoscience, 12(Suppl. ): 30–40 (in Chinese with English Abstract) |
| Mei, M. X., Ma, Y., Zhou, P. K., et al., 1997. Introduction to Carbonate Sedimentology. Seismological Publishing House, Beijing. 1–306 (in Chinese) |
| Mei, M. X., Xu, D., 1996. Cognition on Some Theoretical Problems of the Cyclic Records in Depositional Strata. Geoscience, 10(3): 85–92 (in Chinese with English Abstract) |
| Mei, M. X., Xu, D. B, Zhou, H. R., 2000a. Genetic Types of Meter-Scale Sequences and Fabric Natures of Facies Succession. Journal of China University of Geosciences, 11: 375–382 |
| Mei, M. X., Zhou, H. R., Du, B. M., et al., 2000b. Meso- and Neoproterozoic Sedimentary Sequences in Jixian, Tianjin, Northern China: Division of the First-Order Sequences of the Precambrian Strata (1 800 Ma–600 Ma) and Their Correlation with the Phanerozoic Strata. Sedimentary Geology and Tethyan Geology, 20: 48–59 (in Chinese with English Abstract) |
| Meng, X. H., Ge, M., 2002. The Sedimentary Features of Proterozoic Microspar (MT) Carbonates in China and Their Significance. Episodes, 25: 185–195 doi: 10.18814/epiiugs/2002/v25i3/003 |
| Meng, X. H., Ge, M., 2004. Sequences, Events and Evolution of the Sino-Korean Plate. Science Press, Beijing. 1–483 (in Chinese) |
| Newman, D. K., Banfield, J, F., 2002. Geomicrobiology: How Molecular-Scale Interactions Underpin Biogeochemical System. Science, 296: 1071–1077 doi: 10.1126/science.1010716 |
| Noffke, N., 1998. Multidirected Ripple Marks Rising from Biological and Sedimentological Processes in Modern Lower Supratidal Deposits (Mellum Island, Southern North Sea). Geology, 26: 879–882 |
| Noffke, N., Gerdes, G., Klenke, T., et al., 2001. Microbially Induced Sedimentary Structures—A New Category within the Classification of Primary Sedimentary Structures. Journal of Sedimentary Research, 71(5): 649–656 doi: 10.1306/2DC4095D-0E47-11D7-8643000102C1865D |
| Noffke, N., Gerdes, G., Klenke, T., et al., 2002. Microbially Induced Sedimentary Structures—A New Category within the Classification of Primary Sedimentary Structures—Reply. Journal of Sedimentary Research, 72(4): 589–590 doi: 10.1306/010302720589 |
| O'Connor, M. P., 1972. Classification and Environmental Interpretation of the Cryptalgal Organo-sedimentary "MT" Structure from the Late Precambrian Belt-Purcell Supergroup. Journal of Geology, 80: 592–610 doi: 10.1086/627783 |
| Osleger, D. A., 1990. Subtidal Carbonate Cycles: Implication for Allocyclic versus Autocyclic Controls. Geology, 19: 917–920 |
| Pettijohn, F. J., Potter, P. E., 1964. Atlas and Glossary of Primary Sedimentary Structure. Springer-Verlag, Berlin. 1–370 |
| Pflüger, F., 1999. Matground Structures and Redox Facies. Palaios, 14: 25–39 doi: 10.2307/3515359 |
| Pflüger, F., Gersse, P. G., 1996. Microbial Sand Chip—A Non-Actualistic Sedimentary Structure. Sedimentary Geology, 102: 263–274 doi: 10.1016/0037-0738(95)00072-0 |
| Pollock, M. D., Kah, L. C., Bartley, J. K., 2006. Morphology of MT Structures in Precambrian Carbonates: Influence of Substrate Rheology and Implications for Genesis. Journal of Sedimentary Research, 76: 310–323 doi: 10.2110/jsr.2006.021 |
| Pratt, B. R., 1998a. Syneresis Cracks: Subaqueous Shrinkage in Argillaceous Sediments Caused by Earthquake-Induced Dewatering. Sedimentary Geology, 117: 1–10 doi: 10.1016/S0037-0738(98)00023-2 |
| Pratt, B. R., 1998b. Molar-Tooth Structures in Proterozoic Carbonates: Origin from Synsedimentary Earthquakes, and Implication for the Nature and Evolution of Basin and Marine Sediments. GAS Bulletin, 110: 1028–1045 doi: 10.1130/0016-7606(1998)110<1028:MTSIPC>2.3.CO;2 |
| Pruss, S., Fraiser, M., Bottjer, D. J., 2004. Proliferation of Early Triassic Wrinkle Structures: Implications for Environmental Stress Following the End-Permian Mass Extinction. Geology, 32: 461–464 |
| Qiao, X. F., Gao, L. Z., Peng, Y., 2002. Neoproterozoic in Paleo-Tanlu Fault Zone: Catastrophe·Sequence·Biostratigraphy. Geological Publishing House, Beijing. 1–128 (in Chinese) |
| Qiao, X. F., Song, T. R., Gao, L. Z., 1994. Seisimic Sequence in Carbonate Rocks by Vibarational Liquefaction. Acta Geologica Sinica, 68: 29–35 (in Chinese with English Abstract) |
| Read, J. F., 1985. Carbonate Platform Facies Models. AAPG, 69: 1–21 |
| Reading, H. G., 1996. Sedimentary Environment: Processes, Facies and Stratigraphy. Blackwell Scientific Publication, Oxford. 1–688 |
| Ricketts, B. D., Donaldson, J. A., 1981. Sedimentary History of the Belcher Group of Hudson Bay. In: Compbell, F. H. A., ed., Proterozoic Basins of Canada. Geological Survey of Canada Papers, 81: 235–254 |
| Riding, R., 1994. Evolution of Algal and Cyanobacterial Calcification. In: Bengtson, S., ed., Early Life on Earth, Nobel Symposium 84. Columbia University Press, New York. 426–438 |
| Riding, R., 1997a. Stromatolite Decline: A Brief Reassessment. Facies, 36: 227–230 |
| Riding, R., 1997b. The Term Stromatolite: Toward an Essential Definition. Lethaia, 32: 321–329 |
| Riding, R., 2000. Microbial Carbonates: The Geological Record of Calcified Bacterial-Algal Mats and Biofilms. Sedimentology, 47(1): 179–214 |
| Sandberg, P. A., 1983. An Oscillation Trend in Phanerozoic Non-Skeletal Carbonate Mineralogy. Nature, 305: 19–22 doi: 10.1038/305019a0 |
| Schidlowski, M. A., 1988. 3 800-Million-Year Isotopic Record of Life from Craton in Sedimentary Rock. Nature, 333: 313–318 doi: 10.1038/333313a0 |
| Schubert, J. K., Bottjer, D. J., 1992. Early Triassic Stromatolites as Post-Mass Extinction Disaster Forms. Geology, 20: 883–886 |
| Seilacher, A., Pflüger, F., 1994. From Biomats to Benthic Agriculture: A Biohistoric Revolution. In: Krumbein, W. E., Stal, L. J., eds., Biostabilization of Sediments. Bibliotheks und Informationssystem der Universität, Oldenberg. 97–105 |
| Semikhatov, M. A., Raaben, M. E., 2000. Proterozoic Stromatolite Taxonomy and Biostratigraphy. In: Riding, R., Awramik, S. M., Microbial Sediments. Springer-Verlag, Heideberg. 295–306 |
| Sherman, A. G., James, N. P., Narbonne, G. M., 2000. Sedimentology of a Late Mesoproterozoic Muddy Carbonate Ramp, Northern Baffin Island, Arctic Canada. In: Grotzeinger, J. P., James, N. P., eds., Carbonate Sedimentation and Diagenesis in the Evolving Precambrian World. SEPM Special Publication, 67: 273–294 |
| Song, T. R., Zhao, Z., Wang, C. Y., et al., 1991. Proterozoic Sedimentary Rocks in North-China. Beijing Science and Technology Press, Beijing. 1–239 (in Chinese) |
| Sun, S., 2005. Sedimentology in China: Perspectives and Suggestions. Earth Science Frontiers, 12(2): 3–10 (in Chinese with English Abstract) |
| Tappen, H., 1980. The Paleobiology of Plant Protests. W H Freeman Press, San Francisco. 1–489 |
| Tucker, M. E., Wright, V. P., 1990. Carbonate Sedimentology. Blackwell Scientific Publication, Oxford. 1–482 |
| Walcott, M., 1899. Precambrian Fossiliferous Formation. Bull. Geol. Soc. Am. , 10: 199–244 doi: 10.1130/GSAB-10-199 |
| Walter, M. R., Heys, G. R., 1985. Links between the Rise of the Metazoan and the Decline of Stromatolites. Precambrian Research, 29: 149–174 doi: 10.1016/0301-9268(85)90066-X |
| Wang, H. Z., Shi, X. Y., 1998. Hierarchy of Sedimentary Sequences and Their Sea-Level Cycles—Discussion on Cyclic Periods. Geoscience, 12(1): 1–16 (in Chinese with English Abstract) |
| Warren, L. A., Kauffman, M. E., 2003. Microbial Geoengineers. Science, 299: 1027–1029 doi: 10.1126/science.1072076 |
| Winston, D., Lyons, T., 1993. Sedimentary Cycles in the St. Regis, Empire and Helena Formation of the Middle Proterozoic Belt Supergroup, Northwestern Montana. In: Link, P. K., ed., Geologic Guidebook to the Belt-Purcell Supergroup, Glacier National Park and Vicinity, Montana and Adjacent Canada. Whitefish, Montana. Belt Symposium Ⅲ Field Trip. 21–51 |
| Xing, Y. S., Duan, C. H., Liang, Y. Z., et al., 1985. Palaeontology of the Late Precambrian in China. Geological Publishing House, Beijing. 68–77 (in Chinese) |
| Xing, Y. S., Gao, Z. J., Liu, G. Z., et al., 1989. The Upper Precambrian in China. Geological Publishing House, Beijing. 1–413 (in Chinese) |
| Xing, Y. S., Gao, Z. J., Wang, Z. Q., et al., 1996. Stratigraphic Lexicon of China (Neoproterozoic). Geological Publishing House, Beijing. 1–117 (in Chinese) |
| Yan, Y. Z., 1995. Discovery and Preliminary Study of Megascopic Algae (1 700 Ma) from the Tuanshanzi Formation in Jixian, Tianjin. Acta Micropalaeontologica Sinica, 12(2): 107–126 (in Chinese with English Abstract) |
| Zhao, Z., 1994. Stromatolites. In: Feng, Z. Z., Wang, Y. H., Liu, H. J., et al., eds., Sedimentology in China. Petroleum Industry Press, Beijing. 302–316 (in Chinese) |
| Zhou, H. R., Mei, M. X., Du, B. M., et al., 2006. Study on the Sedimentary Feature of High Frequency Cyclothems of the Wumishan Formation at Jixian, Tianjin. Geoscience, 20(2): 209–215 (in Chinese with English Abstract) |
| Zhu, S., Chen, H., 1995. Megascopic Multicellular Organisms from the 1 700-Million-Old Tuanshanzi Formation in the Jixian Area, North China. Science, 270: 620–622 doi: 10.1126/science.270.5236.620 |
| Zhu, S. X., Xing, Y. S, Zhang, P. Y., 1994. Biostratigraphic Sequence of the Middle-Upper Proterozoic in North-China Platform. Geological Publishing House, Beijing. 1–232 (in Chinese) |
Figures(6)
Copyright © 2013-2020 Journal of Earth Science 鄂ICP备15021562号-2
Tel: +86-27-67885075 Fax: +86-27-67885075 E-mail: xbb@cug.edu.cn
Address: Editorial Office of Journal, China University of Geosciences, Yujiashan, Wuhan, Hubei 430074, P. R. China
Supported by:
Beijing Renhe Information Technology Co. Ltd
E-mail:
info@rhhz.net
DownLoad:
