豫西中元古界龙家园组浅海氧化还原环境重建

石泽远; 张国成; 孙风波; 李倩倩; 杨雯童; 郑德顺; 石泽远; 张国成; 孙风波; 李倩倩; 杨雯童; 郑德顺

doi:10.14027/j.issn.1000-0550.2024.016

[1]

陈知，陈波. 2022. 三峡地区埃迪卡拉纪的浅海氧化还原环境变化：来自碳酸盐岩Ce异常的证据[J]. 地层学杂志，46（2）：109-117.

Chen Zhi, Chen Bo. 2022. Ediacaran shallow-marine redox conditions in the Yangtze Gorges area: Evidence from carbonate cerium anomalies[J]. Journal of Stratigraphy, 46(2): 109-117.

[2]

樊秋爽，夏国清，李高杰，等. 2022. 古海洋氧化还原条件分析方法与研究进展[J]. 沉积学报，40（5）：1151-1171.

Fan Qiushuang, Xia Guoqing, Li Gaojie, et al. 2022. Analytical methods and research progress of redox conditions in the paleo-ocean[J]. Acta Sedimentologica Sinica, 40(5): 1151-1171.

[3]

河南省地质矿产局. 1989. 河南省区域地质志[M]. 武汉：地质出版社：56-77.

Henan Provincial Bureau of Geology and Mineral Resources. 1989. Henan regional geology[M]. Wuhan: Geological Publishing House: 56-77.

[4]

胡国辉，赵太平，周艳艳，等. 2013. 华北克拉通南缘中—新元古代沉积地层对比研究及其地质意义[J]. 岩石学报，29（7）：2491-2507.

Hu Guohui, Zhao Taiping, Zhou Yanyan, et al. 2013. Meso-Neoproterozoic sedimentary formation in the southern margin of the North China Craton and its geological implications[J]. Acta Petrologica Sinica, 29(7): 2491-2507.

[5]

李倩倩，郑德顺. 2023. 豫西中元古界龙家园组二段叠层石特征及其沉积环境分析[J]. 现代地质，37（4）：845-857.

Li Qianqian, Zheng Deshun. 2023. Characteristics of stromatolites and its significance in depositional environment reconstruction of the Mesoproterozoic Longjiayuan Formation(2nd member), western Henan[J]. Geoscience, 37(4): 845-857.

[6]

林治家，陈多福，刘芊. 2008. 海相沉积氧化还原环境的地球化学识别指标[J]. 矿物岩石地球化学通报，27（1）：72-80.

Lin Zhijia, Chen Duofu, Liu Qian. 2008. Geochemical indices for redox conditions of marine sediments[J]. Bulletin of Mineralogy, Petrology and Geochemistry, 27(1): 72-80.

[7]

倪志耀，莫怀毅，刘援朝. 1998. 冕宁前寒武纪沉积岩的铕、铈异常特征及成因解释[J]. 四川地质学报，（4）：20-26.

Ni Zhiyao, Mo Huaiyi, Liu Yuanchao. 1998. Eu and Ce anomalies and genetic explanation for the Precambrian sedimentary rocks in Mianning area, Sichuan[J]. Acta Geologica Sichuan, (4): 20-26.

[8]

尚墨翰. 2020. 碳酸盐岩碘丰度指示的中元古代海洋氧化还原状态[D]. 北京：中国地质大学（北京）：59-73.

Shang Mohan. 2020. Redox evolution of the Mesoproterozoic ocean indicated by carbonate-associated iodine abundance[D]. Beijing: China University of Geosciences (Beijing): 59-73.

[9]

孙龙飞，汤冬杰，周利敏，等. 2020. 华北地台中元古界雾迷山组浅海脉冲式增氧[J]. 古地理学报，22（6）：1181-1196.

Sun Longfei, Tang Dongjie, Zhou Limin, et al. 2020. A pulsed oxygenation in shallow seawater recorded by the Mesoproterozoic Wumishan Formation, North China Platform[J]. Journal of Palaeogeography, 22(6): 1181-1196.

[10]

汤好书，陈衍景，武广，等. 2009. 辽东辽河群大石桥组碳酸盐岩稀土元素地球化学及其对Lomagundi事件的指示[J]. 岩石学报，25（11）：3075-3093.

Tang Haoshu, Chen Yanjing, Wu Guang, et al. 2009. Rare earth element geochemistry of carbonates of Dashiqiao Formation, Liaohe Group, eastern Liaoning province: Implications for Lomagundi Event[J]. Acta Petrologica Sinica, 25(11): 3075-3093.

[11]

田兴磊，雒昆利，王少彬，等. 2014. 长江三峡地区成冰纪—埃迪卡拉纪转换时期微量元素和稀土元素地球化学特征[J]. 古地理学报，16（4）：483-502.

Tian Xinglei, Luo Kunli, Wang Shaobin, et al. 2014. Geochemical characteristics of trace elements and rare earth elements during the Cryogenian-Ediacaran transition in Yangtze Gorges area[J]. Journal of Palaeogeography, 16(4): 483-502.

[12]

万渝生，董春艳，颉颃强，等. 2015. 华北克拉通太古宙研究若干进展[J]. 地球学报，36（6）：685-700.

Wan Yusheng, Dong Chunyan, Xie Hangqiang, et al. 2015. Some progress in the study of Archean basement of the North China Craton[J]. Acta Geoscientia Sinica, 36(6): 685-700.

[13]

王宇航，朱园园，黄建东，等. 2018. 海相碳酸盐岩稀土元素在古环境研究中的应用[J]. 地球科学进展，33（9）：922-932.

Wang Yuhang, Zhu Yuanyuan, Huang Jiandong, et al. 2018. Application of rare earth elements of the marine carbonate rocks in paleoenvironmental researches[J]. Advances in Earth Science, 33(9): 922-932.

[14]

吴明清，欧阳自远，宋云华，等. 1992. 塔里木盆地西缘古海洋氧化还原条件的变化：介壳化石的稀土元素铈异常证据[J]. 中国科学（B辑），（2）：206-215.

Wu Mingqing, Ouyang Ziyuan, Song Yunhua, et al. 1992. Redox variations of the ancient ocean in the western margin of the Tarim Basin: The evidence from Ce anomalies of marine shell fossils[J]. Science in China Series B-Chemistry, Life Sciences & Earth Sciences, (2): 206-215.

[15]

席文祥，裴放. 1997. 河南省岩石地层[M]. 北京：中国地质大学出版社：51-58.

Xi Wenxiang, Pei Fang. 1997. Stratigraphy (lithostratic) of Henan province[M]. Beijing: China University of Geosciences Press: 51-58.

[16]

杨晋东，赵峰华，秦胜飞，等. 2020. 华北克拉通北缘中元古界杨庄组碳酸盐岩地球化学特征及其地质意义[J]. 天然气地球科学，31（2）：268-281.

Yang Jindong, Zhao Fenghua, Qin Shengfei, et al. 2020. Geochemical characteristics and geological significance of carbonate rocks in the Middle Mesoproterozoic Yangzhuang Formation of northern margin of North China Craton[J]. Natural Gas Geoscience, 31(2): 268-281.

[17]

翟明国. 2019. 华北克拉通构造演化[J]. 地质力学学报， 25(5): 722-745.

Zhai Mingguo. 2019. Tectonic evolution of the North China Craton[J]. Journal of Geomechanics, 25(5): 722-745.

[18]

张恒，高林志，周洪瑞，等. 2019. 华北克拉通南缘官道口群和洛峪群的年代学研究新进展：来自凝灰岩SHRIMP锆石U-Pb年龄的新证据[J]. 岩石学报，35（8）：2470-2486.

Zhang Heng, Gao Linzhi, Zhou Hongrui, et al. 2019. Chronology progress of the Guan-daokou and Luoyu Groups in the southern margin of North China Craton: Constraints on zircon U-Pb dating of tuff by means of the SHRIMP[J]. Acta Petrologica Sinica, 35(8): 2470-2486.

[19]

张瑞英，孙勇. 2017. 华北克拉通南部早前寒武纪基底形成与演化[J]. 岩石学报，33（10）：3027-3041.

Zhang Ruiying, Sun Yong. 2017. Formation and evolution of Early Precambrian basement in the southern North China Craton[J]. Acta Petrologica Sinica, 33(10): 3027-3041.

[20]

赵坤，满玲，贺然，等. 2023. 川东北地区晚埃迪卡拉纪灯影期海水氧化还原环境重建[J]. 沉积学报，41（1）：183-195.

Zhao Kun, Man Ling, He Ran, et al. 2023. Redox conditions of the Late Ediacaran Dengying period in northeastern Sichuan, China[J]. Acta Sedimentologica Sinica, 41(1): 183-195.

[21]

左鹏飞，李雨，刘思聪，等. 2019. 华北克拉通南缘中—新元古代沉积演化：以豫西地区黄连垛组和董家组为例[J]. 岩石学报，35（8）：2545-2572.

Zuo Pengfei, Li Yu, Liu Sicong, et al. 2019. Meso-Neoproterozoic sedimentary evolution of the southern margin of the North China Craton: Evidence from the Huanglianduo and Dongjia Formations in the western Henan[J]. Acta Petrologica Sinica, 35(8): 2545-2572.

[22]

Banner J L, Hanson G N. 1990. Calculation of simultaneous isotopic and trace element variations during water-rock interaction with applications to carbonate diagenesis[J]. Geochimica et Cosmochimica Acta, 54(11): 3123-3137.

[23]

Bau M, Koschinsky A, Dulski P, et al. 1996. Comparison of the partitioning behaviours of yttrium, rare earth elements, and titanium between hydrogenetic marine ferromanganese crusts and seawater[J]. Geochimica et Cosmochimica Acta, 60(10): 1709-1725.

[24]

Bolhar R, Kamber B S, Moorbath S, et al. 2004. Characterisation of Early Archaean chemical sediments by trace element signatures[J]. Earth and Planetary Science Letters, 222(1): 43-60.

[25]

Canfield D E. 1998. A new model for Proterozoic ocean chemistry[J]. Nature, 396(6710): 450-453.

[26]

Duda J P, Blumenberg M, Thiel V, et al. 2014. Geobiology of a palaeoecosystem with Ediacara-type fossils: The Shibantan member (Dengying Formation, South China)[J]. Precambrian Research, 255: 48-62.

[27]

Fang H, Tang D J, Shi X Y, et al. 2020. Manganese-rich deposits in the Mesoproterozoic Gaoyuzhuang Formation (ca. 1.58 Ga), North China Platform: Genesis and paleoenvironmental implications[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 559: 109966.

[28]

Holland H D, Lazar B, McCaffrey M. 1986. Evolution of the atmosphere and oceans[J]. Nature, 320(6057): 27-33.

[29]

Lawrence M G, Greig A, Collerson K D, et al. 2006. Rare earth element and yttrium variability in south East Queensland waterways[J]. Aquatic Geochemistry, 12(1): 39-72.

[30]

Li H K, Lu S N, Su W B, et al. 2013. Recent advances in the study of the Mesoproterozoic geochronology in the North China Craton[J]. Journal of Asian Earth Sciences, 72: 216-227.

[31]

Ling H F, Chen X, Li D, et al. 2013. Cerium anomaly variations in Ediacaran–earliest Cambrian carbonates from the Yangtze Gorges area, South China: Implications for oxygenation of coeval shallow seawater[J]. Precambrian Research, 225: 110-127.

[32]

Luo J, Long X P, Bowyer F T, et al. 2021. Pulsed oxygenation events drove progressive oxygenation of the Early Mesoproterozoic ocean[J]. Earth and Planetary Science Letters, 559: 116754.

[33]

Lyons T W, Reinhard C T, Planavsky N J. 2014. The rise of oxygen in Earth's early ocean and atmosphere[J]. Nature, 506(7488): 307-315.

[34]

McLennan M S. 1989. Rare earth elements in sedimentary rocks: Influence of provenance and sedimentary processes[J]. Reviews in Mineralogy and Geochemistry, 21(1): 169-200.

[35]

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[J]. Geochimica et Cosmochimica Acta, 68(2): 263-283.

[36]

Nozaki Y, Zhang J, Amakawa H. 1997. The fractionation between Y and Ho in the marine environment[J]. Earth and Planetary Science Letters, 148(1/2): 329-340.

[37]

Planavsky N J, McGoldrick P, Scott C T, et al. 2011. Widespread iron-rich conditions in the mid-Proterozoic ocean[J]. Nature, 477(7365): 448-451.

[38]

Poulton S W, Fralick P W, Canfield D E. 2010. Spatial variability in oceanic redox structure 1.8 billion years ago[J]. Nature Geoscience, 3(7): 486-490.

[39]

Sarangi S, Mohanty P S, Barik A. 2017. Rare earth element characteristics of Paleoproterozoic cap carbonates pertaining to the Sausar Group, Central India: Implications for ocean paleoredox conditions[J]. Journal of Asian Earth Sciences, 148: 31-50.

[40]

Shang M H, Tang D J, Shi X Y, et al. 2019. A pulse of oxygen increase in the Early Mesoproterozoic ocean at ca. 1.57-1.56 Ga[J]. Earth and Planetary Science Letters, 527: 115797.

[41]

Shields G, Stille P. 2001. Diagenetic constraints on the use of cerium anomalies as palaeoseawater redox proxies: An isotopic and REE study of Cambrian phosphorites[J]. Chemical Geology, 175(1/2): 29-48.

[42]

Sperling E A, Rooney A D, Hays L, et al. 2014. Redox heterogeneity of subsurface waters in the Mesoproterozoic ocean[J]. Geobiology, 12(5): 373-386.

[43]

Tang D J, Shi X Y, Ma J B, et al. 2017. Formation of shallow-water glaucony in weakly oxygenated Precambrian ocean: An example from the Mesoproterozoic Tieling Formation in North China[J]. Precambrian Research, 294: 214-229.

[44]

Tang D J, Shi X Y, Wang X Q, et al. 2016. Extremely low oxygen concentration in mid-Proterozoic shallow seawaters[J]. Precambrian Research, 276: 145-157.

[45]

Tostevin R, Wood R A, Shields G A, et al. 2016. Low-oxygen waters limited habitable space for early animals[J]. Nature Communications, 7: 12818.

[46]

Webb G E, Nothdurft L D, Kamber B S, et al. 2009. Rare earth element geochemistry of scleractinian coral skeleton during meteoric diagenesis: A sequence through neomorphism of aragonite to calcite[J]. Sedimentology, 56(5): 1433-1463.

[47]

Wei W, Frei R, Klaebe R, et al. 2021. A transient swing to higher oxygen levels in the atmosphere and oceans at ~1.4Ga[J]. Precambrian Research, 354: 106058.

[48]

Wyndham T, McCulloch M, Fallon S, et al. 2004. High-resolution coral records of rare earth elements in coastal seawater: Biogeochemical cycling and a new environmental proxy[J]. Geochimica et Cosmochimica Acta, 68(9): 2067-2080.

[49]

Yu Y, Chen Y L, Li D P, et al. 2022. A transient oxygen increase in the Mesoproterozoic ocean at∼1.44 Ga: Geochemical evidence from the Tieling Formation, North China Platform[J]. Precambrian Research, 369: 106527.

[50]

Zhang K, Zhu X K, Wood R A, et al. 2018. Oxygenation of the Mesoproterozoic ocean and the evolution of complex eukaryotes[J]. Nature Geoscience, 11(5): 345-350.

[51]

Zou Y, Liu D N, Zhao F H, et al. 2020. Reconstruction of nearshore chemical conditions in the Mesoproterozoic: Evidence from red and grey beds of the Yangzhuang Formation, North China Craton[J]. International Geology Review, 62(11): 1433-1449.