Latest Wuchiapingian to Earliest Triassic Conodont Zones and δ13Ccarb Isotope Excursions from Deep-Water Sections in Western Hubei Province, South China

被引:0
作者
Bo Yang
Hanxiao Li
Paul B. Wignall
Haishui Jiang
Zhijun Niu
Qian Ye
Qiong Wu
Xulong Lai
机构
[1] China University of Geosciences,School of Earth Sciences
[2] Wuhan Center of Geological Survey,School of Earth & Environment
[3] University of Leeds,State Laboratory of Geobiology and Environmental Geology
[4] China University of Geosciences,State Laboratory of Paleontology and Stratigraphy
[5] Non-ferrous Metals Geological Exploration Bureau of Zhejiang Province,undefined
[6] Nanjing Institute of Geology and Paleontology,undefined
来源
Journal of Earth Science | 2019年 / 30卷
关键词
Dalong Formation; conodonts; δ; C; isotope; Wuchiapingian-Changhsingian boundary; Permian-Triassic boundary;
D O I
暂无
中图分类号
学科分类号
摘要
Deep-water facies sections have advantages of recording complete information across the Permian-Triassic boundary (PTB). Here we present a detailed study on the conodont biostratigraphy and carbon isotope profile ranges from the Wuchiapingian-Changhsingian boundary (WCB) to the PTB of two deep-water facies sections at Zhuqiao and Shiligou in the Middle Yangtze region, western Hubei, South China. Fifteen species and three genera are identified. Eight conodont zones are recognized, in ascending order, they are the Clarkina orientalis, C. wangi, C. subcarinata, C. changxingensis, C. yini, C. meishanensis, Hindeodus parvus and Isarcicella isarcica zones. The onset of deposition of the deep-water siliceous strata of the Dalong Formation in western Hubei began in the Late Wuchiapingian and persisted to the Late Changhsingian. Carbon isotope negative excursions occur near both the WCB and PTB in both sections. The WCB δ13Ccarb negative excursion is in the C. orientalis and C. wangi zones. The PTB δ13Ccarb negative excursion began in the C. yini Zone and extended to the I. isarcica Zone. The absence of several Changhsingian zones may indicate the difficulty of extracting conodonts from siliceous strata or the presence of an intra-Changhsingian hiatus.
引用
收藏
页码:1059 / 1074
页数:15
相关论文
共 198 条
[51]  
Wang Y(2011)Calibrating the End-Permian Mass Extinction Science 334 1367-1372
[52]  
Henderson C(2013)High-Resolution Δ Earth and Planetary Science Letters 375 156-165
[53]  
Kolar-Jurkovšek T(2014)C National Science Review 1 492-495
[54]  
Jurkovšek B(2012) Chemostratigraphy from Latest Guadalupian through Earliest Triassic in South China and Iran Earth and Planetary Science Letters 353–354 12-21
[55]  
Nestell G P(2012)The End-Permian Mass Extinction: A Still Unexplained Catastrophe Nature Geoscience 6 52-56
[56]  
Korte C(1989)Geochemical Evidence from Bio-Apatite for Multiple Oceanic Anoxic Events during Permian-Triassic Transition and the Link with End-Permian Extinction and Recovery AAPG Bulletin 73 1247-1269
[57]  
Kozur H W(2012)Two Pulses of Extinction during the Permian-Triassic Crisis Science 338 366-370
[58]  
Kozur H W(2005)Mesozoic and Cenozoic Sedimentary History of South China Albertiana 33PARTII 129-138
[59]  
Kozur H W(2004)Lethally Hot Temperatures during the Early Triassic Greenhouse Geological Science and Technology Information 23 30-34
[60]  
Kozur H W(2004)Triassic in Chaohu, Anhui Province, Guide to the Mid-Symposium Field Excursion of the International Symposium on the Triassic Chronostratigraphy and Biotic Recovery Canadian Journal of Earth Sciences 41 323-330
12345678910