早三叠世

(重定向自下三叠世

早三叠世三叠纪三个之首,自251.902Ma持续到247.2Ma (百万年前)。这一世的岩石统称为下三叠统

早三叠世
251.902 ± 0.024 – 247.2 百万年前
下三叠统砂岩
地质年代
三叠纪主要分界
-250 —
-245 —
-240 —
-235 —
-230 —
-225 —
-220 —
-215 —
-210 —
-205 —
-200 —
三叠纪时间表
直轴:百万年前
词源
年代地层名称上三叠统
地质年代名称早三叠世
名称是否正式Formal
具体信息
天体地球
适用区域全球(ICS)
适用时标ICS时间表
定义
地质年代单位
年代地层单位
名称是否正式正式
下边界定义牙形石物种小欣德牙形石首次出现
下边界GSSP位置中国浙江梅山
31°04′47″N 119°42′21″E / 31.0798°N 119.7058°E / 31.0798; 119.7058
GSSP批准时间2001[3]:102–114
上边界定义未正式定义
候选的定义上边界
  • 牙形石物种Chiosella timorensis首次出现
  • MT1n地磁带的基底
上边界GSSP候选

早三叠世是中生代的第一个世,它之前是乐平世(古生代晚二叠世),之后是中三叠世。早三叠世可被分为印度期奥伦尼克期。印度期又可分为格里斯巴赫期迪纳尔期,奥伦尼克期也可分为史密斯期斯派思期[4]

下三叠统在以前也被称为斯基泰阶。在欧洲,下三叠统的大部分由斑砂岩统组成,它是一个陆上红层岩石地层学单位。

生物圈历经早三叠世和一部分中三叠世,才从地球史上规模最大的灭绝事件——二叠纪-三叠纪灭绝事件中恢复过来。第二次灭绝事件——史密斯-斯派斯期边界事件发生在奥伦尼克期。[5]

气候

 
普托拉纳高原西伯利亚暗色岩玄武岩组成。

早三叠世的气候(特别是盘古大陆内部)相当干旱少雨,沙漠广布;极地则表现温带气候。以菊石的分布为依据推测,共时来看,极地到赤道的温度梯度相当平坦,可能使得热带物种可以轻易扩张到极地。[6]:374–395

早三叠世大多数炎热气候[7]:1–10都可能由西伯利亚暗色岩的火山活动导致,这也是二叠纪-三叠纪灭绝事件的主要成因,并加速了全球变暖的速度。研究发现早三叠世的气候变化无常,常常出现相比之下幅度、速度都很大的温度变化,引发史密斯-斯派斯期边界事件。[8]:57–60[9]:366–370[10][11]:169–178

生物

动植物相

二叠纪-三叠纪灭绝事件同时终结了二叠纪和古生代,使得幸存生物的生活相当艰难。

早三叠世的生物逐渐从灭绝事件中恢复过来,受灭绝事件严重程度和早三叠世严酷气候的影响,恢复过程花了数百万年。[12]许多珊瑚腕足动物软体动物棘皮动物和其他一些无脊椎动物灭绝了。二叠纪南半球的植被由舌羊齿属统治,三叠纪也不复存在了。[13]:28372辐鳍鱼等其他种群似乎受到灭绝事件影响较小,[14]:348–362体型似乎不是灭绝期间的选择性因子。[15]:106–147[16]:727–741海洋中和陆地上的生态恢复呈现不同的模式。受大灭绝影响,早三叠世动物相缺乏生物多样性,且高度同质。陆上生态恢复花了3000万年。[17]:759–765

陆地生物群

最普遍的陆生脊椎动物是一种小型植食性动物——合弓纲水龙兽属。水龙兽广泛分布在盘古大陆上,很多人认为它是大灭绝后的先锋生物(常被反对[18]:610463)。它和非哺乳类犬齿兽亚目鼩龙兽属三尖叉齿兽属同时出现于盘古大陆南部。主龙形类也在这时出现,代表性物种为引鳄属(奥伦尼克期-拉丁期)。[19]:188这个群体包括鳄科恐龙(包括鸟类)的祖先。恐龙形态类的脚印化石在奥伦尼克期已有。[20]:1107–1113

三叠纪刚开始时,植物相裸子植物为主,后来在格里斯巴赫-迪纳尔期生态危机阶段快速变化为石松为主(如肋木属)。这一变化与二叠纪舌羊齿属植物相的灭绝刚好重合。[13]斯派斯期,植物相变回裸子植物和羊齿植物为主。[21]:911–924这些变化反映全球降水和温度的变化。[13]

海洋生物群

在海洋中,最普遍的早三叠世海生硬壳无脊椎动物是双壳纲腹足纲菊石海胆,以及几种腕足动物。最早的牡蛎出现于早三叠世,生长在菊石的壳上。[22]:253–260微生物岩礁很普遍,可能是因为与后生动物礁缺乏竞争。[23]:62–74不过,在环境允许的情况下,短暂的后生动物礁在奥伦尼克期重新出现了。[24]:693–697菊石在大量死亡后,于早三叠世展现全面繁盛的状况。[25]:1118–1121

水生脊椎动物在大灭绝后发生分化。

鱼类:典型三叠纪辐鳍鱼类,如南方鱼比耶鱼古鲳属锥体鱼属翼鳕属副半椎鱼科龙鱼属在靠近二叠纪-三叠纪交界处出现,而新鳍亚纲则在稍后才展现出高多样性。[15]许多鱼类物种在早三叠世都有广泛分布。腔棘鱼纲多样性达到峰值,并展现出多样的生活姿态(叛逆腔棘鱼属)。软骨鱼纲古贝茨无尖齿鱼属滑齿鲨属、部分板鳃亚纲弓鲨目物种,以及尤金齿目最后的幸存者(卡士尼鲨属法登鲨属)。

两栖动物:相对大型的海生离片椎类两栖动物,如隐次龙旺扎螈,再印度期奥伦尼克期覆盖了相当大的地域。这些鳄形两栖类的化石分布在格陵兰斯匹次卑尔根岛巴基斯坦马达加斯加

爬行动物:在海洋中,最早的水生爬行动物在早三叠世出现。[26]:e88987它们的后代在中生代主宰了海洋。湖北鳄目鱼龙超目鳍龙超目是奥伦尼克期最早一批海洋爬行动物(如短吻龙属巢湖龙属歌津鱼龙属湖北鳄短尾鱼龙属短头鱼龙属瞳龙属)。其他海洋爬行动物,如长颈龙属瑞士龙属滤齿龙属楯齿龙目海龙目则保持到中三叠世。[26]安尼期鱼龙目海帝鱼龙属是最早的海洋主要掠食者之一,可以捕食与自身体型相近的猎物,它占据的生态位可以和今日的逆戟鲸比拟。[27]:1393–1397

史密斯-斯派斯期边界事件

早三叠世奥伦尼克期发生一次重要的灭绝事件,其时间靠近史密斯期和斯派斯期的界限。这次灭绝事件的主要受害者[28]菊石牙形石,以及几种在二叠纪—三叠纪灭绝事件后幸存的古生代合弓纲物种,包括二齿兽类(比如三叠纪早期曾构成陆生动物四分之三的水龙兽)和兽头类(如三叠纪早期的顶级掠食者麝喙兽)。在史密斯-斯派斯期边界事件后,蜥形纲主龙类伪鳄演替成为优势陆生动物,鱼龙鳍龙海洋爬行动物也在这次灭绝后迅速多样化。

植物相也变化剧烈。它从印度期和史密斯期以石松(如肋木属)为主,变为斯派斯期以裸子植物羊齿植物为主。[21]:911–924[29]:169–178这些变化是全球气温和降水变化的反映。松柏门中生代大多数时候的主要植物。直到最近,这次发生于约249.4 Ma[30]:1–16的灭绝事件才得以确认其存在。[31]

 
早三叠世和安尼期海洋捕食者:[26] 1. 旺扎螈;2. 法登龙属;3. 龙鱼属;4. 叛逆腔棘鱼属;5. 霍瓦蜥属;6. 比耶鱼属;7. 隐次龙;8. 古鲳属;9. 弓鲨目;10. Mylacanthus;11. 长颈龙属;12. 瞳龙属;13. Ticinepomis;14. 混鱼龙属;15. 杯椎鱼龙科;16. 新鲨类;17. 短头鱼龙属骨架;18. 楯齿龙属

史密斯-斯派斯期边界事件与西伯利亚暗色岩的晚期喷发有关,反映为全球变暖[8]牙形石氧同位素的研究发现,温度可能在三叠纪最初200万年迅速升高,最终使得史密斯期热带海平面温度达到40°C。[32]灭绝事件本身发生于晚史密斯期,当时全球气温又突然下降;不过仅靠气温不足以形成史密斯-斯派斯期边界事件,还有好几个其他因素同时起作用。[10][30]:1–16

在海洋中,许多大型动物都不再分布于热带,仅剩一些大型鱼类,[33]:1025–1046和一些无法移动的软体动物。只有能对抗高温的物种存活了下来,约一半的双壳纲物种灭绝。[34]在陆地上,回归线附近几乎不存在肉眼可见的生物。[9]

也存在生命迅速恢复的证据,尽管它们也仅是地方性的。有些地区有异乎寻常的高生物多样性(如最早的斯派斯期巴黎生物区),[35]:e1602159[36]:19657这支持复杂的食物网和多重营养级

另见

参考

  1. ^ McElwain, J. C.; Punyasena, S. W. Mass extinction events and the plant fossil record. Trends in Ecology & Evolution. 2007, 22 (10): 548–557. PMID 17919771. doi:10.1016/j.tree.2007.09.003. 
  2. ^ Payne, J. L.; Lehrmann, D. J.; Wei, J.; Orchard, M. J.; Schrag, D. P.; Knoll, A. H. Large Perturbations of the Carbon Cycle During Recovery from the End-Permian Extinction. Science. 2004, 305 (5683): 506–9. PMID 15273391. doi:10.1126/science.1097023. 
  3. ^ Hongfu, Yin; Kexin, Zhang; Jinnan, Tong; Zunyi, Yang; Shunbao, Wu. The Global Stratotype Section and Point (GSSP) of the Permian-Triassic Boundary (PDF). Episodes. June 2001, 24 (2) [8 December 2020]. doi:10.18814/epiiugs/2001/v24i2/004 . (原始内容存档 (PDF)于2021-08-28). 
  4. ^ Tozer, Edward T. Lower Triassic stages and ammonoid zones of arctic Canada. Geological Survey of Canada. 1965. OCLC 606894884. 
  5. ^ Widmann, Philipp; Bucher, Hugo; Leu, Marc; Vennemann, Torsten; Bagherpour, Borhan; Schneebeli-Hermann, Elke; Goudemand, Nicolas; Schaltegger, Urs. Dynamics of the Largest Carbon Isotope Excursion During the Early Triassic Biotic Recovery. Frontiers in Earth Science. 2020, 8 (196): 1–16. doi:10.3389/feart.2020.00196 . 
  6. ^ Brayard, Arnaud; Bucher, Hugo; Escarguel, Gilles; Fluteau, Frédéric; Bourquin, Sylvie; Galfetti, Thomas. The Early Triassic ammonoid recovery: Paleoclimatic significance of diversity gradients. Palaeogeography, Palaeoclimatology, Palaeoecology. September 2006, 239 (3–4). Bibcode:2006PPP...239..374B. doi:10.1016/j.palaeo.2006.02.003. 
  7. ^ Preto, Nereo; Kustatscher, Evelyn; Wignall, Paul B. Triassic climates — State of the art and perspectives. Palaeogeography, Palaeoclimatology, Palaeoecology. April 2010, 290 (1–4). doi:10.1016/j.palaeo.2010.03.015. 
  8. ^ 8.0 8.1 Romano, Carlo; Goudemand, Nicolas; Vennemann, Torsten W.; Ware, David; Schneebeli-Hermann, Elke; Hochuli, Peter A.; Brühwiler, Thomas; Brinkmann, Winand; Bucher, Hugo. Climatic and biotic upheavals following the end-Permian mass extinction. Nature Geoscience. 21 December 2012, 6 (1). S2CID 129296231. doi:10.1038/ngeo1667. 
  9. ^ 9.0 9.1 Sun, Y.; Joachimski, M. M.; Wignall, P. B.; Yan, C.; Chen, Y.; Jiang, H.; Wang, L.; Lai, X. Lethally Hot Temperatures During the Early Triassic Greenhouse. Science. 18 October 2012, 338 (6105). Bibcode:2012Sci...338..366S. PMID 23087244. S2CID 41302171. doi:10.1126/science.1224126. 
  10. ^ 10.0 10.1 Goudemand, Nicolas; Romano, Carlo; Leu, Marc; Bucher, Hugo; Trotter, Julie A.; Williams, Ian S. Dynamic interplay between climate and marine biodiversity upheavals during the early Triassic Smithian -Spathian biotic crisis. Earth-Science Reviews. August 2019, 195. Bibcode:2019ESRv..195..169G. doi:10.1016/j.earscirev.2019.01.013 . 
  11. ^ Schneebeli-Hermann, Elke. Regime Shifts in an Early Triassic Subtropical Ecosystem. Frontiers in Earth Science. December 2020, 8: 588696. doi:10.3389/feart.2020.588696 . 
  12. ^ Chen, Zhong-Qiang; Benton, Michael J. The timing and pattern of biotic recovery following the end-Permian mass extinction. Nature Geoscience. 27 May 2012, 5 (6): 375–383. Bibcode:2012NatGe...5..375C. doi:10.1038/ngeo1475. 
  13. ^ 13.0 13.1 13.2 Hochuli, Peter A.; Sanson-Barrera, Anna; Schneebeli-Hermann, Elke; Bucher, Hugo. Severest crisis overlooked—Worst disruption of terrestrial environments postdates the Permian–Triassic mass extinction. Scientific Reports. 24 June 2016, 6 (1). Bibcode:2016NatSR...628372H. PMC 4920029 . PMID 27340926. doi:10.1038/srep28372. 
  14. ^ Smithwick, Fiann M.; Stubbs, Thomas L. Phanerozoic survivors: Actinopterygian evolution through the Permo‐Triassic and Triassic‐Jurassic mass extinction events. Evolution. 2 February 2018, 72 (2). PMC 5817399 . PMID 29315531. doi:10.1111/evo.13421 . 
  15. ^ 15.0 15.1 Romano, Carlo; Koot, Martha B.; Kogan, Ilja; Brayard, Arnaud; Minikh, Alla V.; Brinkmann, Winand; Bucher, Hugo; Kriwet, Jürgen. Permian-Triassic Osteichthyes (bony fishes): diversity dynamics and body size evolution. Biological Reviews. February 2016, 91 (1). PMID 25431138. S2CID 5332637. doi:10.1111/brv.12161. 
  16. ^ Puttick, Mark N.; Kriwet, Jürgen; Wen, Wen; Hu, Shixue; Thomas, Gavin H.; Benton, Michael J.; Angielczyk, Kenneth. Body length of bony fishes was not a selective factor during the biggest mass extinction of all time. Palaeontology. September 2017, 60 (5). doi:10.1111/pala.12309 . 
  17. ^ Sahney, Sarda; Benton, Michael J. Recovery from the most profound mass extinction of all time. Proceedings of the Royal Society B: Biological Sciences. 15 January 2008, 275 (1636). PMC 2596898 . PMID 18198148. doi:10.1098/rspb.2007.1370. 
  18. ^ Modesto, Sean P. The Disaster Taxon Lystrosaurus: A Paleontological Myth. Frontiers in Earth Science. December 2020, 8. doi:10.3389/feart.2020.610463 . 
  19. ^ Foth, Christian; Ezcurra, Martín D.; Sookias, Roland B.; Brusatte, Stephen L.; Butler, Richard J. Unappreciated diversification of stem archosaurs during the Middle Triassic predated the dominance of dinosaurs. BMC Evolutionary Biology. 15 September 2016, 16 (1). PMC 5024528 . PMID 27628503. doi:10.1186/s12862-016-0761-6 . 
  20. ^ Brusatte, Stephen L.; Niedźwiedzki, Grzegorz; Butler, Richard J. Footprints pull origin and diversification of dinosaur stem lineage deep into Early Triassic. Proceedings of the Royal Society B: Biological Sciences. 6 October 2010, 278 (1708). PMC 3049033 . PMID 20926435. doi:10.1098/rspb.2010.1746 . 
  21. ^ 21.0 21.1 Schneebeli-Hermann, Elke; Kürschner, Wolfram M.; Kerp, Hans; Bomfleur, Benjamin; Hochuli, Peter A.; Bucher, Hugo; Ware, David; Roohi, Ghazala. Vegetation history across the Permian–Triassic boundary in Pakistan (Amb section, Salt Range). Gondwana Research. April 2015, 27 (3). Bibcode:2015GondR..27..911S. doi:10.1016/j.gr.2013.11.007. 
  22. ^ Hautmann, Michael; Ware, David; Bucher, Hugo. Geologically oldest oysters were epizoans on Early Triassic ammonoids. Journal of Molluscan Studies. August 2017, 83 (3). doi:10.1093/mollus/eyx018 . 
  23. ^ Foster, William J.; Heindel, Katrin; Richoz, Sylvain; Gliwa, Jana; Lehrmann, Daniel J.; Baud, Aymon; Kolar‐Jurkovšek, Tea; Aljinović, Dunja; Jurkovšek, Bogdan; Korn, Dieter; Martindale, Rowan C.; Peckmann, Jörn. Suppressed competitive exclusion enabled the proliferation of Permian/Triassic boundary microbialites. The Depositional Record. 20 November 2019, 6 (1). PMC 7043383 . PMID 32140241. doi:10.1002/dep2.97 . 
  24. ^ Brayard, Arnaud; Vennin, Emmanuelle; Olivier, Nicolas; Bylund, Kevin G.; Jenks, Jim; Stephen, Daniel A.; Bucher, Hugo; Hofmann, Richard; Goudemand, Nicolas; Escarguel, Gilles. Transient metazoan reefs in the aftermath of the end-Permian mass extinction. Nature Geoscience. 18 September 2011, 4 (10). Bibcode:2011NatGe...4..693B. doi:10.1038/ngeo1264. 
  25. ^ Brayard, A.; Escarguel, G.; Bucher, H.; Monnet, C.; Bruhwiler, T.; Goudemand, N.; Galfetti, T.; Guex, J. Good Genes and Good Luck: Ammonoid Diversity and the End-Permian Mass Extinction. Science. 27 August 2009, 325 (5944). Bibcode:2009Sci...325.1118B. PMID 19713525. S2CID 1287762. doi:10.1126/science.1174638. 
  26. ^ 26.0 26.1 26.2 Scheyer, Torsten M.; Romano, Carlo; Jenks, Jim; Bucher, Hugo. Early Triassic Marine Biotic Recovery: The Predators' Perspective. PLOS ONE. 19 March 2014, 9 (3). Bibcode:2014PLoSO...988987S. PMC 3960099 . PMID 24647136. doi:10.1371/journal.pone.0088987 . 
  27. ^ Fröbisch, Nadia B.; Fröbisch, Jörg; Sander, P. Martin; Schmitz, Lars; Rieppel, Olivier. Macropredatory ichthyosaur from the Middle Triassic and the origin of modern trophic networks. Proceedings of the National Academy of Sciences. 22 January 2013, 110 (4). Bibcode:2013PNAS..110.1393F. PMC 3557033 . PMID 23297200. doi:10.1073/pnas.1216750110 . 
  28. ^ Galfetti, Thomas; Hochuli, Peter A.; Brayard, Arnaud; Bucher, Hugo; Weissert, Helmut; Vigran, Jorunn Os. Smithian-Spathian boundary event: Evidence for global climatic change in the wake of the end-Permian biotic crisis. Geology. 2007, 35 (4): 291. Bibcode:2007Geo....35..291G. doi:10.1130/G23117A.1. 
  29. ^ Goudemand, Nicolas; Romano, Carlo; Leu, Marc; Bucher, Hugo; Trotter, Julie A.; Williams, Ian S. Dynamic interplay between climate and marine biodiversity upheavals during the early Triassic Smithian -Spathian biotic crisis. Earth-Science Reviews. August 2019, 195. Bibcode:2019ESRv..195..169G. doi:10.1016/j.earscirev.2019.01.013 . 
  30. ^ 30.0 30.1 Widmann, Philipp; Bucher, Hugo; Leu, Marc; Vennemann, Torsten; Bagherpour, Borhan; Schneebeli-Hermann, Elke; Goudemand, Nicolas; Schaltegger, Urs. Dynamics of the Largest Carbon Isotope Excursion During the Early Triassic Biotic Recovery. Frontiers in Earth Science. 2020, 8 (196). doi:10.3389/feart.2020.00196 . 
  31. ^ Hallam, A.; Wignall, P. B. Mass Extinctions and Their Aftermath . Oxford University Press, UK. 1997: 143. ISBN 978-0-19-158839-6. Extinctions with and at the close of the Triassic 
  32. ^ Marshall, Michael. Roasting Triassic heat exterminated tropical life. New Scientist. 18 October 2012 [2021-10-24]. (原始内容存档于2021-10-26). 
  33. ^ Romano, Carlo; Jenks, James F.; Jattiot, Romain; Scheyer, Torsten M.; Bylund, Kevin G.; Bucher, Hugo. Marine Early Triassic Actinopterygii from Elko County (Nevada, USA): implications for the Smithian equatorial vertebrate eclipse. Journal of Paleontology. 19 July 2017, 91 (5). doi:10.1017/jpa.2017.36 . 
  34. ^ Hallam, A.; Wignall, P. B. Mass Extinctions and Their Aftermath . Oxford University Press, UK. 1997: 144. ISBN 978-0-19-158839-6. 
  35. ^ Brayard, Arnaud; Krumenacker, L. J.; Botting, Joseph P.; Jenks, James F.; Bylund, Kevin G.; Fara, Emmanuel; Vennin, Emmanuelle; Olivier, Nicolas; Goudemand, Nicolas; Saucède, Thomas; Charbonnier, Sylvain; Romano, Carlo; Doguzhaeva, Larisa; Thuy, Ben; Hautmann, Michael; Stephen, Daniel A.; Thomazo, Christophe; Escarguel, Gilles. Unexpected Early Triassic marine ecosystem and the rise of the Modern evolutionary fauna. Science Advances. 15 February 2017, 3 (2). Bibcode:2017SciA....3E2159B. PMC 5310825 . PMID 28246643. doi:10.1126/sciadv.1602159 . 
  36. ^ Smith, Christopher P.A.; Laville, Thomas; Fara, Emmauel; Escarguel, Gilles; Olivier, Nicolas; Vennin, Emmanuelle; Goudemand, Nicolas; Bylund, Kevin G.; Jenks, James F.; Stephen, Daniel A.; Hautmann, Michael; Charbonnier, Sylvain; Krumenacker, L. J.; Brayard, Arnaud. Exceptional fossil assemblages confirm the existence of complex Early Triassic ecosystems during the early Spathian. Scientific Reports. 4 October 2021, 11. doi:10.1038/s41598-021-99056-8. 

阅读更多

  • Martinetto, Edoardo; Tschopp, Emanuel; Gastaldo, Robert (编). Nature through Time: Virtual field trips through the Nature of the past. Springer International Publishing. 2020. ISBN 978-3-030-35057-4. 

外部链接

Template:Triassic Footer