Freezing and thawing structures: An evidence of cold climate in the Neoproterozoic Liantuo Formation in Shennongjia of northern margin of Yangtze Craton
Wang Yu-Chong1,2, Kuang Hong-Wei2, Peng Nan2, Liu Yong-Qing2, Fan Zheng-Xiu2, Xia Xiao-Xu1,2, Chen Xiao-Shuai2, Zheng Hang-Hai1,2, Sun Yu-Xiang3
1 China University of Geosciences(Beijing),Beijing 100083; 2 Institute of Geology,Chinese Academy of Geological Sciences,Beijing 100037; 3 College of Geoscience and Surveying Engineering,China University of Mining & Technology(Beijing),Beijing 100083
Abstract The palaeoclimates(i.e.,greenhouse or icehouse)in South China before the Sturtian period of the Neoproterozoic Cryogenian are still controversial. Recently,a series of soft sedimentary deformation structures(SSDSs)were recognized in the upper part of the Liantuo Formation of the Shennongjia in the northern margin of the Yangtze Craton. They are represented by gray-green sandy veins host in purple mudstone or sandstone matrix. Based on their marco-mirco morphology,texture and structure,and geochemistry characteristics,we interpret them to be a type of freezing and thawing structures developed under cold climates,or perhaps being suggestive of the existence of permafrost. According to their morphologies,the documented Liantuo SSDSs are categorized into four main types,namely reticulate,dendritic veins bearing rigidity fracture,along with banded,mottled veins bear plastic deformation. our results suggest that the characteristics of the veins were more matrix debris supported less clay minerals,weak particles directionality lining the wall,loss of Fe(Ⅲ),indicating that the veins had been liquefied. Moreover the veins are more depleted in trace element such as Bi,Pr,W,La than those in the matrix. However,different REE distribution patterns of veins and matrices also indicate that there is no effect on the alteration during the later diagenesis. The dual structures in debris rocks(i.e.,low Sr/Ba ratio of 0.05 to 0.25 versus low V/Ni ratio of 0.05 to 0.5)suggest that the structures were developed in microenvironments like floodplains of meandering rivers. The low CIA values of 55-65and negative carbon and oxygen isotope negative excursion(i.e.,δ13CPDB of-17‰~-14‰,δ18OPDB of-15‰~-13‰) in the veins and matrices,in contrast,indicate that they would probably have formed in cold climates. All of these observations suggest that the Shennongjia area in the northern margin of the Yangtze Craton was located in the cold periglacial environments before the start of Stuartian Period in the Neoproterozoic Cryogenian. Furthermore,the paper opens up a new research idea and approach for the recognition of the cold climatic conditions in late sedimentary period of the Liantuo Formation,particularly the response on the “Snowball Earth”event in Yangtze Craton. Meanwhile,it also provides a new scientific evidence and sedimentary index for the division of glacial period in Yangtze Craton and correlation at home and abroad.
Fund:Co-funded by the National Key Research and Development Proram of China(No.2016YFC0601001),the China Geological Survey Project(No. DD20160120-01),the National Natural Science Foundation of China(No.41472082),China Commission of Stratigraphy and the Project of Shengnongjia Global Geopark
Corresponding Authors:
Kuang Hong-Wei,born in 1969,is a professor and doctoral supervisor in the Institute of Geology,CAGS. She is mainly engaged in sedimentology, stratigraphy and petroleum geology. E-mail: kuanghw@126.com. Peng Nan,born in 1983,is a research assistant in the Institute of Geology,CAGS. He is mainly engaged in sedimentary geology and palaeogeography. E-mail: pengnan19830120@126.com.
About author: Wang Yu-Chong,born in 1992,is a master candidate of paleontology and stratigraphy in China University of Geosciences(Beijing). He is mainly engaged in sedimentology. E-mail: wyc@cugb.edu.cn.
Cite this article:
Wang Yu-Chong,Kuang Hong-Wei,Peng Nan et al. Freezing and thawing structures: An evidence of cold climate in the Neoproterozoic Liantuo Formation in Shennongjia of northern margin of Yangtze Craton[J]. JOPC, 2018, 20(4): 579-594.
Wang Yu-Chong,Kuang Hong-Wei,Peng Nan et al. Freezing and thawing structures: An evidence of cold climate in the Neoproterozoic Liantuo Formation in Shennongjia of northern margin of Yangtze Craton[J]. JOPC, 2018, 20(4): 579-594.
[1] 崔之久. 1983. 试论冰缘期的划分依据与对比. 冰川冻土, 5(1): 13-20. [Cui Z J.1983. A discussion on the evidences of division of periglacial ages and their correlation. Journal of Glaciology and Geocryology, 5(1): 13-20] [2] 崔之久,谢又予. 1984. 论中国东北、华北晚更新世晚期多年冻土南界与冰缘环境. 地质学报,(2): 81-94. [Cui Z J,Xie Y Y.1984. On the southern boundary of permafrost and periglacial environment during the late period of late Pleistocene in north and northeast China. Acta Geologica Sinica,(2): 81-94] [3] 崔之久,朱诚. 1988. 中国冰缘地貌研究述评与展望. 冰川冻土, 10(3): 304-311. [Cui Z J,Zhu C.1988. Commentaries and prospects of the study on periglacial geomorphology. Journal of Glaciology and Geocryology, 10(3): 304-311] [4] 冯连君,储雪蕾,张启锐,张同钢. 2003. 化学蚀变指数(CIA)及其在新元古代碎屑岩中的应用. 地学前缘, 10(4): 539-544. [Feng L Q,Chu X L,Zhang Q R,Zhang T G.2003. CIA(chemical index of alteration)and its applications in the Neoproterozoic clastic rocks,Earth Science Frontiers, 10(4): 539-544] [5] 高林志,尹崇玉,丁孝忠,王泽九,张恒. 2015. 华南地区新元古代年代地层标定及地层对比. 地球学报,37(5): 533-545. [Gao L Z,Yin C Y,Ding X Z,Wang Z J, Zhang H.2015. Rating data of the Neoproterozoic chronostratigraphy and stratigraphic correlation in South China. Acta Geoscientica Sinica,37(5): 533-545] [6] 高振家. 2000. 中国岩石地层辞典. 湖北武汉: 中国地质大学出版社,259. [Gao Z J.2000. Dictionary of the Lithostratigraphic Unit of China. Wuhan: China University of Geoscience Press,259] [7] 高维,张传恒. 2009. 长江三峡黄陵花岗岩与莲沱组凝灰岩的锆石SHRIMP U-Pb年龄及其构造地层意义. 地质通报, 28(1): 45-50. [Gao W,Zhang C H.2009. Zircon SHRIMP U-Pb ages of the Huangling granite and the tuff beds from Liantuo Formation in the Three Gorges area of Yangtze River,China and its geological significance. Geological Bulletin of China, 28(1): 45-50] [8] 官开萍,田力,安志辉,叶琴,胡军,童金南. 2016. 湖北神农架西部南华纪地层序列及其区域对比. 地学前缘, 23(6): 236-245. [Guan K P,Tian L,An Z H,Ye Q,Hu J,Tong J N.2016. Stratigraphic succession of the Nanhuan Period in the Shennongjia area in western Hubei and its regional correlation. Earth Science Frontiers, 23(6): 236-245] [9] 湖北省地质矿产局. 1990. 湖北省区域地质志. 北京: 地质出版社,44-63. [Hubei BGMR.1990. Regional Geology of Hubei Province. Beijing: Geological Publishing House,44-63] [10] 黄建中,唐晓珊. 1996. 对峡东莲沱组与湖南板溪群对比问题的一点浅见. 地层学杂志,20(3): 232-236. [Huang J Z,Tang X S.1996. On the correlation between the Liantuo Formation of the Yangtze Gorge and the Banxi Group of Hunan. Journal of Stratigraphy,20(3): 232-236] [11] 黄晶,储雪蕾,张启锐,冯连君. 2007. 新元古代冰期及其年代. 地学前缘, 14(2): 251-258. [Huang J,Chu X L,Zhang Q R,Feng L J.2007. Constraints on the age of Neoproterozoic global glaciations. Earth Science Frontiers, 14(2): 251-258] [12] 景先庆,杨振宇,仝亚博,王恒,韩志锐,徐颖超. 2016. 华南早新元古代莲沱组地层磁倾角偏低研究及其古地理意义. 地质通报, 35(11): 1797-1806. [Jing X Q,Yang Z Y,Tong Y B,Wang H,Han Z R,Xu Y C.2016. Inclination shallowing study of the Early-Neoproterozoic Liantuo Formation in South China and its paleogeographic implications. Geological Bulletin of China, 35(11): 1797-1806] [13] 景先庆,杨振宇,仝亚博,王恒,徐颖超. 2018. 三峡地区新元古代莲沱组底部凝灰岩锆石SHRIMP U-Pb年代学及其地质意义. 吉林大学学报(地球科学版), 48(1): 165-180. [Jing X Q,Yang Z Y,Tong Y B,Wang H,Xu Y C.2018. A SHRIMP U-Pb zircon geochronology of a tuff bed from the bottom of Liantuo Formation in the Three Gorges Area and its geological implications. Journal of Jilin University(Earth Science Edition), 48(1): 165-180] [14] 李建华,张岳桥,施炜,李海龙,董树文. 2009. 大巴山前陆带东段神农架地区构造变形研究. 地质力学学报, 15(2): 162-177. [Li J H,Zhang Y Q,Shi W,Li H L,Dong S W.2009. Tectonic deformation features of Shennongjia region in Eastern Dabashan Foreland structural belt. Journal of Geomechanics, 15(2): 162-177] [15] 李铨,冷坚. 1987. 神农架上前寒武系. 天津: 天津科学技术出版社,31-36. [Li Q,Leng J.1987. The Upper Precambrian in the Shennongjia Region. Tianjin: Tianjin Science and Technology Press,31-36] [16] 刘鸿允. 1991. 中国晚前寒武纪构造、古地理与沉积演化. 地质科学,(4): 309-316. [Liu H Y.1991. Precambrian tectonics,paleogeography and sedimentary evolution in China. Chinese Journal of Geology,(4): 309-316] [17] 刘鸿允. 1999. 中国中东部晚前寒武纪地层与地质演化. 北京: 科学出版社,86-142. [Liu H Y.1999. Late Precambrian stratigraphy in east-central China and implications for geological evolution. Beijing: Science Press,86-142] [18] 刘鸿允,沙庆安. 1963. 长江峡东区震旦系新见. 地质科学, 4(4): 177-187. [Liu H Y,Sha Q A.1963. New sight on the Sinian in eastern Yangtze Gorges area. Chinese Journal of Geology,(4): 177-187] [19] 马国干,李华芹,张自超. 1984. 华南地区震旦纪时限范围的研究. 中国地质科学院宜昌地质矿产研究所文集, 8: 1-30. [Ma G G,Li H Q,Zhang Z C.1984. An investigation of the age limits of the Sinian System in South China,Bull. Yichang inst.geol. Mineral. Res, 8: 1-30] [20] 彭学军,刘耀荣,吴能杰,陈建超,李建清. 2004. 扬子陆块东南缘南华纪地层对比. 地层学杂志, 28(4): 354-359. [Peng X J,Liu Y R,Wu N J,Chen J C,Li J Q.2004. Correlation of the Nanhuan Strata on the Southern Margin of the Yangtze Landmass. Journal of Stratigraphy, 28(4): 354-359] [21] 齐靓,余文超,杜远生,周琦,郭华,王佳武,王萍,徐源. 2015. 黔东南华纪铁丝坳期—大塘坡期古气候的演变: 来自CIA的证据. 地质科技情报, 34(6): 47-57. [Qi L,Yu W C,Du Y S,Zhou Q,Guo H,Wang J W,Wang P,Xu Y.2015. Paleoclimate evolution of the Cryogenian Tiesi'ao Formation-Datangpo Formation in eastern Guizhou Province: Evidence from the chemical index of alteration. Geological Science and Technology Information, 34(6): 47-57] [22] 全国地层委员会. 2001. 中国地层指南及中国地层指南说明书. 修订版. 北京: 地质出版社,42. [Nations Commission on Stratigraphy of China. 2001. China Stratigraphy Guide and Instructions of China Stratigraphy Guide. Beijing: Geological Publishing House,42] [23] 邵菁清,杨守业. 2012. 化学蚀变指数(CIA)反映长江流域的硅酸盐岩化学风化与季风气候?科学通报, 57(11): 933-942. [Shao J Q,Yang S Y.2012. Does chemical index of alteration(CIA)reflect silicate weathering and monsoonal climate in the Changjiang River basin? Chinese Science Bulletin, 57(11): 933-942] [24] 舒良树. 2012. 华南构造演化的基本特征. 地质通报, 31(7): 1035-1053. [Shu L S.2012. An analysis of principal features of tectonic evolution in South China Block. Geological Bulletin of China, 31(7): 1035-1053] [25] 孙建中. 1981. 松辽平原冰缘期的划分. 地理科学,(2): 71-78,100. [Sun J Z.1981. Quaternary periglacial stages of the Songliao Plain. Scientia Geographica Sinica,(2): 71-78,100] [26] 孙建中,王淑英,王雨灼,周亚杰,林泽蓉,张庆云,陈树汉. 1985. 东北末次冰期的古环境. 第四纪研究, 6(1): 82-89. [Sun J Z,Wang S Y,Wang Y Z,Zhou Y J,Lin Z R,Zhang Q Y,Chen S H.1985. Paleoenvironment of the last glacial stage in northeast China. Quaternary Sciences, 6(1): 82-89] [27] 田景春,张翔. 2016. 沉积地球化学. 北京: 地质出版社,64-131. [Tian J C,Zhang X.2016. Sedimentary Geochemistry. Beijing: Geological Publishing House,64-131] [28] 谢又予. 1985. 试论东北地区多年冻土形成的气候条件及其演化. 冰川冻土, 7(4): 323-330. [Xie Y Y.1985. Climatic condition in the formation and evolution of permafrost in Northeast China. Journal of Glaciology & Geocryology, 7(4): 323-330] [29] 徐小涛,邵龙义. 2018. 利用泥质岩化学蚀变指数分析物源区风化程度时的限制因素. 古地理学报, 20(3): 515-522. [Xu X T,Shao L Y.2018. Limiting factors in utilization of chemical index of alteration of mudstones to quantify the degree of weathering in provenance. Journal of Palaeogeography(Chinese Edition), 20(3): 515-522] [30] 王保来. 1991. 冰缘环境研究的一些进展. 冰川冻土, 13(3): 273-280. [Wang B L.1991. Some advances in periglacial environment studies. Journal of Glaciology and Geocryology, 13(3): 273-280] [31] 王自强,尹崇玉,高林志,柳永清,唐烽,张传恒. 2006. 用化学地层学研究新元古代地层划分和对比. 地学前缘, 13(6): 268-279. [Wang Z Q,Yin C Y,Gao L Z,Liu Y Q,Tang F,Zhang C H.2006. Chemostratigraphic studies to explain Neoproterozoic stratigraphic division and correlation. Earth Science Frontiers, 13(6): 268-279] [32] 王自强,尹崇玉,高林志,柳永清,唐烽,张传恒. 2006. 宜昌三斗坪地区南华系化学蚀变指数特征及南华系划分、对比的讨论. 地质论评, 52(5): 577-585. [Wang Z Q,Yin C Y,Gao L Z,Liu Y Q,Tang F,Zhang C H.2006. The character of the chemical index of alteration and discussion of subdivision and correlation of the Nanhua System in Yichang area. Geological Review, 52(5): 577-585] [33] 尹崇玉,高林志. 2013. 中国南华系的范畴、时限及地层划分. 地层学杂志, 37(4): 534-541. [Yin C Y,Gao L Z.2013. Definition,time limit and stratigraphic subdivision of the Nanhuan System in China. Journal of Stratigraphy, 37(4): 534-541] [34] 尹崇玉,刘敦一,高林志,王自强,邢裕盛,简平,石玉若. 2003. 南华系底界与古城冰期的年龄: SHRIMP Ⅱ定年证据. 科学通报, 48(16): 1721-1725. [Yin C Y,Liu D Y,Gao L Z,Wang Z Q,Xing Y S,Jian P,Shi R Y.2003. Age of the lower boundary of Nanhaan and of Gucheng glaciation: Evidence of SHRIMP U-Pb dating. Chinese Science Bulletin, 48(16): 1721-1725] [35] 张启锐. 1995. 湖北省宜昌县震旦系南沱组成因的新认识. 地质科学,(2): 147-152. [Zhang Q R.1995. The origin of Sinian Nantuo Formation in Yichang County,Hubei Province. Chinese Journal of Geology,(2): 147-152] [36] 张启锐,储雪蕾,张同钢,冯连君. 2002. 从“全球冰川”到“雪球假说”: 关于新元古代冰川事件的最新研究. 高校地质学报, 8(4): 473-481. [Zhang Q R,Chu X L,Zhang T G,Feng L J.2002. From global glaciation to Snowball Earth: Recent researches on the Neoproterozoic glaciation events. Geological Journal of China Universities, 8(4): 473-481] [37] 张启锐,储雪蕾,冯连君. 2008. 南华系“渫水河组”的对比及其冰川沉积特征的探讨. 地层学杂志, 32(3): 19-25. [Zhang Q R,Chu X L,Feng L J.2008. A correlation of the“Xieshuihe Formation” Nanhuan System with a discussion to its glacial sedimentary stractures. Journal of Stratigraphy, 32(3): 19-25] [38] 张雄,曾佐勋,潘黎黎,曾智辉,彭练红,徐大良,魏云许,刘浩,邓欣. 2016. 对湖北大洪山地区一套紫红色砂—砾岩系沉积年代的再认识: 碎屑锆石U-Pb年龄及其地质意义. 地质通报, 35(7): 1069-1080. [Zhang X,Zeng Z X,Pan L L,Zeng Z H,Peng L H,Xu D L,Wei Y X,Liu H,Deng X.2016. Recognition of the sedimentation age of a series of purple-red colored glutenite sedimentary rocks in Dahong Mountain area,northern Hubei Province: Detrital zircon U-Pb geochronology and its geological significance. Geological Bulletin of China, 35(7): 1069-1080] [39] 赵小明,刘圣德,张权绪,吴健辉,曾波夫,廖宗明,杨刚忠,李方会. 2011. 鄂西长阳南华系地球化学特征的气候指示意义及地层对比. 地质学报, 85(4): 576-585. [Zhao X M,Liu S D,Zhang Q X,Wu J H,Zeng B F,Liao Z M,Yang G Z,Li F H.2011. Geochemical characters of the Nanhua System in Changyang,Western Hubei Province and its implication for climate and sequence correlation. Acta Geologica Sinica, 85(4): 576-585] [40] 赵自强. 1985. 长江三峡地区生物地层学(1),震旦纪分册. 北京: 地质出版社,1-106. [Zhao Z Q.1985. Biostratigraphy of the Yangtze Gorge area(1): Sinian. Beijing: Geological Publishing House,1-106] [41] 郑永飞. 2003. 新元古代岩浆活动与全球变化. 科学通报, 48(16): 1705-1720. [Zheng Y F.2003. Neoproteroterozoic magmatic activity and global change. Chinese Science Bulletin, 48(16): 1705-1720] [42] 周传明. 2016. 扬子区新元古代前震旦纪地层对比. 地层学杂志, 40(2): 120-135. [Zhou C M.2016. Neoproterozoic lithostratigraphy and correlation across the Yangtze Block,South China. Journal of Stratigraphy, 40(2): 120-135] [43] 周小进,杨帆. 2007. 中国南方新元古代—早古生代构造演化与盆地原型分析. 石油实验地质, 29(5): 446-451. [Zhou X J,Yang F.2007. Tectonic evolution and prototypes analysis from neoproterozoic to early paleozoic in south China. Petroleum Geology and Experiment, 29(5): 446-451] [44] Bodiselitsch B,Koeberl C,Master S,Reimold W U.2005. Estimating Duration and Intensity of Neoproterozoic Snowball Glaciations from Ir Anomalies. Science, 308: 239-242. [45] Boynton W V.1984. Cosmochemistry of the rare earth elements: Condensation and evaporation processes. Developments in Geochemistry, 2(2): 63-114. [46] Calver C R,Black L P,Everard J L,Seymour D B.2004. U-Pb zircon age constraints on late Neoproterozoic glaciation in Tasmania. Geology, 32(10): 893-896. [47] Condon D,Zhu M,Bowring S,Wang W,Yang A, Jin Y.2005. U-Pb ages from the Neoproterozoic Doushantuo Formation,China. Science, 308: 95-98. [48] Cox R,Lowe D R,Cullers R L.1995. The influence of sediment recycling and basement composition on evolution of mudrock chemistry in the southwestern United States. Geochimica et Cosmochimica Acta, 59(14): 2919-2940. [49] Du Q D,Wang Z,Wang J,Qiu Y S,Jiang X S.2013. Geochronology and paleoenvironment of the pre-Sturtian glacial strata: Evidence from the Liantuo Formation in the Nanhua rift basin of the Yangtze Block,South China. Precambrian Research, 233: 118-131. [50] Evans D A D,Li Z X,Kirschvink J L,Wingate M T D.2000. A high-quality mid-Neoproterozoic paleomagnetic pole from South China,with implications for ice ages and the breakup configuration of Rodinia. Precambrian Research, 100(1-3): 313-334. [51] Fairchild I J,Kennedy M J.2007. Neoproterozoic glaciation in the Earth System. Journal of the Geological Society, 164(5): 895-921. [52] Hoffman P F,Kaufman A J,Halverson G P,Schrag D P.1998. A Neoproterozoic snowball Earth. Science, 281: 1342-1346. [53] Hoffmann K H,Condon D J,Bowring S A,Crowley J L.2004. U-Pb zircon date from the Neoproterozoic Ghaub Formation,Namibia: Constraints on Marinoan glaciation. Geology, 32(9): 817-820. [54] Hoffman P F,Li Z X.2009. A palaeogeographic context for Neoproterozoic glaciation. Palaeogeography, Palaeoclimatology, Palaeoecology, 277(4): 158-172. [55] Jouzel G L, Russell R J, Suozzo, Russell G L, White J W C.1987. Simulations of the HDO and $H_2^{18}$O atmospheric cycles using the NASA GISS General Circulation Model: The seasonal cycle for present-day conditions. Journal of Geophysical Research-Atmospheres, 92: 14739-14760. [56] Jing X Q,Yang Z,Tong Y,Han Z.2015. A revised paleomagnetic pole from the mid-Neoproterozoic Liantuo Formation in the Yangtze block and its paleogeographic implications. Precambrian Research, 268: 194-211. [57] Kennedy M J,Runnegar B,Prave A R,Hoffmann K H,Arthur M A.1998. Two or four Neoproterozoic glaciations? Geology, 26(12): 1059-1063. [58] Kirschvink J L.1992. Late Proterozoic low-latitude global glaciation: The snowball earth. In: The Proterozoic Biosphere: A Multidisciplinary Study. Cambridge University Press,51-52. [59] Lan Z W,Li X H,Zhu M,Zhang Q,Li Q L.2015. Revisiting the Liantuo Formation in Yangtze Block,South China: SIMS U-Pb zircon age constraints and regional and global significance. Precambrian Research, 263: 123-141. [60] Mclennan S M.1993. Weathering and Global Denudation. Journal of Geology, 101(2): 295-303. [61] Nesbitt H W.1979. Mobility and fractionation of rare earth elements during weathering of a granodiorite. Nature, 279: 206-210. [62] Nesbitt H W,Young G M.1982. Early proterozoic climates and plate motions inferred from major element chemistry of lutites. Nature, 299: 715-717. [63] Nesbitt H W,Young G M.1989. Formation and diagenesis of weathering profiles. Journal of Geology, 97(2): 129-147. [64] Panahi A,Young G M,Rainbird R H.2000. Behavior of major and trace elements(including REE)during Paleoproterozoic pedogenesis and diagenetic alteration of an Archean granite near Ville Marie,Québec,Canada. Geochimica et Cosmochimica Acta, 64(13): 2199-2220. [65] Yang Z,Sun Z,Yang T,Pei J.2004. A long connection(750-380 Ma)between South China and Australia: Paleomagnetic constraints. Earth and Planetary Science Letters, 220(3): 423-434. [66] Zhang S,Evans D A D,Li H,Wu H,Jiang G,Dong,J,Zhao Q L,Raub T D,Yang T S.2013. Paleomagnetism of the late Cryogenian Nantuo Formation and paleogeographic implications for the South China Block. Journal of Asian Earth Sciences, 72: 164-177.