华北中元古代鱼骨状方解石: 成因机制和古环境意义<sup>* </sup>

doi:10.7605/gdlxb.2017.02.018

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Abstract Herringbone calcite(HC),characterized by the alternation of sub-millimetric light and dark jagged bands,is a special type of carbonate mineral phase that mainly developed during the Archean. Early studies suggest that HC is a kind of inorganic chemical precipitation,formed in anoxic,calcium carbonate supersaturated,and precipitation inhibitor (Fe²⁺,Mn²⁺)￣rich seawater. Therefore,it has been used as an indicator of anoxic seawater conditions,and its abundance decreases over geologic time is thought to have reflected the increasing oxidation of the ocean. However,recent studies suggest that the genesis of HC might have been variable. For the first time,we have found HC in the microbial reef of the Mesoproterozoic Gaoyuzhuang Formation in the North China Platform. Macroscopically,these HCs mainly occurred in the voids of microbial reef as void-filling,distinct from their Archean counterparts which largely occurred as seafloor precipitation. Microscopically,the HC fiber shows a characteristic of rotated distinction along the crystal growth direction,indicating that the internal crystals of each HC fiber was once rotated from the bottom to the top. This is in accordance with the spherulitic growth pattern,therefore,requiring the participation of the calcite precipitation inhibitors. The secular decrease in HC abundance and the changes in their occurrence pattern from seafloor precipitation to void-filling,suggest that HC precipitation inhibitors should be redox-sensitive elements,which have been continuously removed from seawater with the oxidation of the ocean. Thus,we think that the major inhibitors for HC precipitation are Fe²⁺ and Mn²⁺,and HC can be used as a mineral indicator for anoxic environment,which is consistent with the Ce anomaly results(without obvious anomalies)in the microbial reef and the presence of strong inhibitor effect of Fe²⁺. In addition,both microscopic and ultramicroscopic observations revealed that there are a large number of bacterial filamentous relics and closely associated organominerals concentrated along the axis of HC fibers,indicating that the microbes have provided favorable sites for the initial nucleation and subsequent growth of HC crystals.

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	Articles by authors
	Tang Dongjie
	Shi Xiaoying
	Zhang Wenhao
	Liu Yun
	Wu Jinjian

Key words： Mesoproterozoic, Gaoyuzhuang Formation, microbial reef, herringbone calcite, precipitation inhibitor, potential paleoredox indicator

Received: 04 November 2016 Published: 01 April 2017

Fund:Co-funded by the National Natural Science Foundation of China(Nos.41402024,41272039)and the Fundamental Research Funds for the Central Universities(No.2652014063)

About author: About the first author Tang Dongjie,born in 1985,is an associate professor of China University of Geosciences(Beijing). He is engaged in geobiology and Precambrian geology. E-mail: dongjtang@126.com.

Cite this article:

Tang Dongjie,Shi Xiaoying,Zhang Wenhao et al. Mesoproterozoic herringbone calcite from North China Platform:Genesis and paleoenvironmental significance[J]. JOPC, 2017, 19(2): 227-240.

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http://journal09.magtechjournal.com/gdlxb/EN/10.7605/gdlxb.2017.02.018 OR http://journal09.magtechjournal.com/gdlxb/EN/Y2017/V19/I2/227

1 高林志,张传恒,刘鹏举,丁孝忠,王自强,张彦杰. 2009. 华北—江南地区中、新元古代地层格架的再认识. 地球学报,30(4): 433-446. [Gao L Z,Zhang C H,Liu P J,Ding X Z,Wang Z Q,Zhang Y J. 2009. Recognition of Meso- and Neoproterozoic stratigraphic framework in North and South China. Acta Geosicientia Sinica,30(4): 433-446.]
2 李怀坤,朱士兴,相振群,苏文博,陆松年,周红英,耿建珍,李生,杨锋杰. 2010. 北京延庆高于庄组凝灰岩的锆石 U-Pb 定年研究及其对华北北部中元古界划分新方案的进一步约束. 岩石学报,26(7): 2131-2140. [Li H K,Zhu S X,Xiang Z Q,Su W B,Lu S N,Zhou H Y,Geng J Z,Li S,Yang F J. 2010. Zircon U-Pb dating on tuff bed from Gaoyuzhuang Formation in Yanqing,Beijing: Further constraints on the new subdivision of the Mesoproterozoic stratigraphy in the northern North China Craton. Acta Petrologica Sinica,26(7): 2131-2140.]
3 陆松年,李惠民. 1991. 蓟县长城系大红峪组火山岩的单颗粒锆石 U-Pb 法准确定年. 地球学报,22(1): 137-146. [Lu S N,Li H M. 1991. A precise U-Pb single zircon age determination for the volcanics of Dahongyu Formation,Changcheng system in Jixian. Acta Geosicientia Sinica,22(1): 137-145.]
4 Bartley J,Kah L. 2004. Marine carbon reservoir,C org -C carb coupling,and the evolution of the Proterozoic carbon cycle. Geology, 32(2): 129-132.
5 Bartley J K,Kah L C,Frank T D,Lyons T W. 2015. Deep-water microbialites of the Mesoproterozoic Dismal Lakes Group: Microbial growth,lithification,and implications for coniform stromatolites. Geobiology,13(1): 15-32.
6 Bau M,Dulski P. 1996. Distribution of yttrium and rare-earth elements in the Penge and Kuruman Iron-Formations,Transvaal Supergroup,South Africa. Precambrian Research,79(1): 37-55.
7 Byrne R,Sholkovitz E. 1996. Marine chemistry and geochemistry of the lanthanides. In: Gschneider K A Jr,Eyring L R(eds),Handbook on the Physics and Chemistry of the Rare Earths,23. Amsterdam: Elsevier,497-593.
8 de Wet C B,Frey H M,Gaswirth S B,Mora C I,Rahnis M,Bruno C R. 2004. Origin of meter-scale submarine cavities and herringbone calcite cement in a Cambrian microbial reef,Ledger Formation(USA). Journal of Sedimentary Research,74(6): 914-923.
9 Folk R L. 1987. Detection of organic matter in thin-sections of carbonate rocks using a white card. Sedimentary Geology,54(3): 193-200.
10 German C R,Elderfield H. 1990. Application of the Ce anomaly as a paleoredox indicator: The ground rules. Paleoceanography,5(5): 823-833.
11 German C R,Holliday B P,Elderfield H. 1991. Redox cycling of rare earth elements in the suboxic zone of the Black Sea. Geochimica et Cosmochimica Acta,55(12): 3553-3558.
12 Grotzinger J P,James N P. 2000. Precambrian carbonates: Evolution of understanding. SEPM,Special Publication,67: 3-22.
13 Guo H,Du Y S,Lian Z,Yang J H,Huang H. 2013. Trace and rare earth elemental geochemistry of carbonate succession in the Middle Gaoyuzhuang Formation,Pingquan Section: Implications for Early Mesoproterozoic ocean redox conditions. Journal of Palaeogeography,2(2): 209-221.
14 Kamber B S,Webb G E. 2001. The geochemistry of late Archaean microbial carbonate: Implications for ocean chemistry and continental erosion history. Geochimica et Cosmochimica Acta,65(15): 2509-2525.
15 Keith H D,Padden F J. 1963. A phenomenological theory of spherulitic crystallization. Journal of Applied Physics,34(8): 2409-2421.
16 Ling H F,Chen X,Li D,Wang D,Shields-Zhou G A,Zhu M Y. 2013. Cerium anomaly variations in Ediacaran-earliest Cambrian carbonates from the Yangtze Gorges area,South China: Implications for oxygenation of coeval shallow sea-water. Precambrian Research,225: 110-127.
17 Lu S,Zhao G,Wang H,Hao G. 2008. Precambrian metamorphic basement and sedimentary cover of the North China Craton: A review. Precambrian Research,160(1): 77-93.
18 McLennan S M. 2001. Relationships between the trace element composition of sedimentary rocks and upper continental crust. Geochemistry,Geophysics,Geosystems,2(4): 203-226.
19 Mei M X. 2007. 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 China University of Geosciences,18(3): 191-209.
20 Mei M X. 2008. Sedimentary features and implications for the Precambrian non-stromatolitic carbonate succession: A case study of the Mesoproterozoic Gaoyuzhuang Formation at the Qiangou Section in Yanqing County of Beijing. Acta Geologica Sinica(English Edition),82(2): 295-309.
21 Meyer H J. 1984. The influence of impurities on the growth rate of calcite. Journal of Crystal Growth,66(3): 639-646.
22 Nothdurft L D,Webb G E,Kamber B S. 2004. Rare earth element geochemistry of Late Devonian reefal carbonates,Canning Basin,Western Australia: Confirmation of a seawater REE proxy in ancient limestones. Geochimica et Cosmochimica Acta,68(2): 263-283.
23 Planavsky N,Bekker A,Rouxel O J,Kamber B,Hofmann A,Knudsen A,Lyons T W. 2010. Rare earth element and yttrium compositions of Archean and Paleoproterozoic Fe formations revisited: New perspectives on the significance and mechanisms of deposition. Geochimica et Cosmochimica Acta,74(22): 6387-6405.
24 Slack J F,Grenne T,Bekker A,Rouxel O J,Lindberg P A. 2007. Suboxic deep seawater in the late Paleoproterozoic: Evidence from hematitic chert and iron formation related to seafloor-hydrothermal sulfide deposits,central Arizona,USA. Earth and Planetary Science Letters,255(1): 243-256.
25 Sumner D Y,Grotzinger J P. 1996a. Herringbone calcite: Petrography and environmental significance. Journal of Sedimentary Research,66(3): 419-429.
26 Sumner D Y,Grotzinger J P. 1996b. Were kinetics of Archean calcium carbonate precipitation related to oxygen concentration?Geology,24(2): 119-122.
27 Sumner D Y,Tourre S A. 2000. Ferrous Iron and the Crystallographic Characteristics of Herringbone Calcite. In 31st IGC Meeting,Rio de Janeiro,Abstracts.
28 Tang D J,Shi X Y,Jiang G Q. 2013a. Mesoproterozoic biogenic thrombolites from the North China Platform. International Journal of Earth Sciences,102(2): 401-413.
29 Tang D J,Shi X Y,Jiang G Q. 2014. Sunspot cycles recorded in Mesoproterozoic carbonate biolaminites. Precambrian Research,248: 1-16.
30 Tang D J,Shi X Y,Jiang G Q,Pei Y P, Zhang W H. 2013b. Microfabrics in Mesoproterozoic microdigitate stromatolites: Evidence of biogenicity and organomineralization at micron and nanometer scales. Palaios,28(3): 178-194.
31 Tang D J,Shi X Y,Jiang G Q,Pei Y P, Zhang W H. 2013c. Environment controls on Mesoproterozoic thrombolite morphogenesis: A case study from the North China Platform. Journal of Palaeogeography,2(3): 275-296.
32 Tang D J,Shi X Y,Shi Q,Wu J J,Song G Y,Jiang G Q. 2015. Organomineralization in Mesoproterozoic giant ooids. Journal of Asian Earth Sciences,107: 195-211.
33 Tang D J,Shi X Y,Wang X Q,Jiang G Q. 2016. Extremely low oxygen concentration in mid-Proterozoic shallow seawaters. Precambrian Research,276: 145-157.
34 Tourre S A,Sumner D Y. 1999. Cave-filling herringbone calcite from a middle Eocene carbonate platform,Egypt;crystal morphology and geochemistry of an unusual carbonate cement. Abstracts with Programs—Geological Society of America,31(7):280.
35 Wan Y,Zhang Q,Song T. 2003. SHRIMP ages of detrital zircons from the Changcheng System in the Ming Tombs area,Beijing: Constraints on the protolith nature and maximum depositional age of the Mesoproterozoic cover of the North China Craton. Chinese Science Bulletin,48(22): 2500-2506.
36 Webb G E,Kamber B S. 2000. Rare earth elements in Holocene reefal microbialites: A new shallow seawater proxy. Geochimica et Cosmochimica Acta,64(9): 1557-1565.