重新厘定“四川运动”与青藏高原初始隆升的时代、背景:黄陵背斜构造形成的启示

地学前缘 ›› 2010, Vol. 17 ›› Issue (4): 206-217.

重新厘定“四川运动”与青藏高原初始隆升的时代、背景:黄陵背斜构造形成的启示

葛肖虹,王敏沛,刘俊来

1吉林大学地球科学学院, 吉林长春 130061
2中国地质大学(北京) 地球科学与资源学院, 北京 100083
3中国地质大学地质过程与矿产资源国家重点实验室, 北京 100083

收稿日期:2009-12-08 修回日期:2010-04-28 出版日期:2010-07-01 发布日期:2010-07-01
作者简介:葛肖虹(1938—),男,教授,博士生导师,长期从事中国区域大地构造学教学与研究。Email: gxhbj2004@yahoo.com.cn
基金资助:
国家自然科学基金项目(90814006);教育部“111”计划项目(B07011)

Redefining the Sichuan Movement and the age and background of Qingzang Plateaus first uplift: The implication of Huangling anticline and its enlightenment.

GE Xiao-Gong, WANG Min-Pei, LIU Dun-Lai

1College of Earth Sciences, Jilin University, Changchun 130061, China
2School of Earth Sciences and Resources, China University of Geosciences(Beijing), Beijing 100083, China
3State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Beijing 100083, China

Received:2009-12-08 Revised:2010-04-28 Online:2010-07-01 Published:2010-07-01

摘要/Abstract

摘要：

迄今为止对华南地区古—中生界褶皱构造变形形成时期的主流认识是晚中生代的燕山期,但是笔者近年通过对黄陵背斜露头剖面的观察、地质图分析和前人认识的资料汇总,认为黄陵背斜经历过早白垩世以前印支—晚燕山运动的构造变形,晚白垩世、古—始新世经历了伸展隆升或变质核杂岩的形成过程,最终的挤压褶皱构造变形发生在渐新世末大约246 Ma,即新生代的喜山运动中期。通过研究得到两点启示:(1)引起华南地区NNE走向挤压褶皱与推覆构造最后定型的“四川运动”不是发生在早年谭锡畴和李春昱根据当时资料定位的晚白垩世的燕山期,而应该是古近纪渐新世末的喜山期;形成“四川运动”的宏观背景是始新世中期—渐新世太平洋板块运动的转向,即从43~36 Ma以前的太平洋板块向NNW俯冲转为向NWW俯冲,以致构成对中国东部包括扬子—华南板块在内的NWW向挤压,形成中国东部从华南到东北以NNE走向为主的挤压褶皱、推覆构造变形及相应的盆山地貌,和李四光早年提出挽近时期形成的“新华夏系”构造地貌轮廓一致。(2)中新世印度洋中脊快速扩张,引发印—澳板块向NNE俯冲、推挤引起青藏高原的初次隆升,形成NWW向展布的青藏—闽粤初始高原,黄陵背斜是初始高原与 “新华夏系”盆山地貌的构造结点,具有双重构造特征,经历了中—上新世高原隆升剥蚀和夷平,现今山盆起伏的构造地貌是上新世晚期至早更新世晚期(36~08 Ma)以来快速隆升的产物。

关键词: 黄陵背斜, &ldquo, 四川运动&rdquo, 时代与背景, 太平洋板块运动转向, 青藏高原初次隆升, 青藏&mdash, 闽粤初始高原

Abstract:

Although the folding of the Paleozoic and Mesozoic in South China has hitherto ascribed to the results of Yanshanian tectonic stage in the Late Mesozoic, we argue that there were three stages of deformation, an early and a late compression, and an extension between them, based on the observations of outcrops of the Huangling anticline, the analysis of the specific geology map, the seismic crosssection and stratigraphic column of Jianghan Basin and Qianjiang depression, and the summarization of the existing data. The Huangling anticline was formed primarily due to the tectonic deformation before the Early Cretaceous in the Early Indosinian and Late Yanshanian tectonic stage. Extensional uplifting and exhumation of metamorphic core complexes dominated the deformation in the Late Cretaceous. There was a final compressive folding at about 24.6 Ma, in the middle stage of Himalayan movement. The “Sichuan movement” that eventually formed the NNE trending compressive fold and nappethrust tectonics in South China was the results of the Himalayan tectonic event between the Oligocene and the Miocene, rather than the Sichuan movement in the Late Yanshanian of the Late Cretaceous proposed by Tan Xichou and Li Chunyu based on evidences recognized at that time. In that period, the Pacific Plate changed its direction of subduction between the middle Eocene and the Oligocene, from NWN before 4336 Ma to NWW. A NWWSEE oriented compressive stress field was formed in Eastern China including the Yangtze and South China plates, which resulted in the occurrence of NEN trending fold and nappethruststructures and the homologous basinmountain landforms in a vast area in eastern China from South to Northeast China. Correspondingly, the tectonic movement resulted in the basinrange landforms and coincided with the outline of Neocathaysian tectonic system raised by Lee Siguang in early days. In the Miocene, the ridge of Indian Ocean spread very fast, and then led the IndianAustralian Plate subducting to NNE, which formed the initial QingzangMinyue Plateau with NWW trending. The Huangling anticline was a tectonic knot of the initial QingzangMinyue Plateau and those basins and mountains belong to Neocathaysian tectonic system, so it has the features of two sides. It went through the uplift and denudation during the Miocene and the Pliocene, and the tectonic landforms of basinmountain nowadays were caused by intensive uplifting during the Late Pliocene and the Early Pleistocene (360.8 Ma).

Key words: Huangling anticline, period and tectonic setting of Sichuan movement, rotation of the Pacific Plate, first uplift of Qingzang Plateau, initial QingzangMinyue Plateau

中图分类号:

P542.1

葛肖虹, 王敏沛, 刘俊来. 重新厘定“四川运动”与青藏高原初始隆升的时代、背景:黄陵背斜构造形成的启示 [J]. 地学前缘, 2010, 17(4): 206-217.

GE Xiao-Gong, WANG Min-Pei, LIU Dun-Lai. Redefining the Sichuan Movement and the age and background of Qingzang Plateaus first uplift: The implication of Huangling anticline and its enlightenment.[J]. Earth Science Frontiers, 2010, 17(4): 206-217.

[1]	申俊峰，王书豪，徐立为，罗照华，李金春，刘海明，聂潇，秦玉良，彭自栋，牛刚，杜佰松，刘家军. 西秦岭岗岔—克莫金矿区石英闪长玢岩多金属“珠滴构造”及其找矿意义[J]. 地学前缘, 2019, 26(5): 222-242.
[2]	温利刚，曾普胜，詹秀春，范晨子，孙冬阳，王广，袁继海，费晓杰. 迤纳厂矿床：一个“白云鄂博式”铁铜稀土矿床[J]. 地学前缘, 2018, 25(6): 308-329.
[3]	操应长，徐琦松，王健. 沉积盆地“源-汇”系统研究进展[J]. 地学前缘, 2018, 25(4): 116-131.
[4]	潘仁芳，陈美玲，张超谟，潘进. 济阳坳陷渤南洼陷古近系页岩油“甜点”地震预测及影响因素分析[J]. 地学前缘, 2018, 25(4): 142-154.
[5]	王登红，刘丽君，侯江龙，代鸿章，于扬，代晶晶，田世洪. 初论甲基卡式稀有金属矿床“五层楼＋地下室”勘查模型[J]. 地学前缘, 2017, 24(5): 1-7.
[6]	赵正，王登红，陈毓川，刘善宝，方贵聪，梁婷，郭娜欣，王少轶. “九龙脑成矿模式”及其深部找矿示范：“五层楼＋地下室”勘查模型的拓展[J]. 地学前缘, 2017, 24(5): 8-16.
[7]	王少轶，赵正，方贵聪，欧阳翔，陈振宇，侯可军. 赣南樟(东坑)-九(龙脑)钨多金属矿床矿物学、年代学特征及其地质意义[J]. 地学前缘, 2017, 24(5): 120-130.
[8]	周学慧,丁文龙,昌伦杰,牛玉杰,尹帅,张敏,孙雅雄. 三端员定型”法识别滨岸相砂岩储层隔夹层：以塔里木盆地哈得逊油田东河砂岩为例[J]. 地学前缘, 2017, 24(5): 328-338.
[9]	苏丕波，梁金强，张子健，沙志彬. 神狐海域扩散型水合物在地震反射剖面上的“亮点”与“暗点”分析[J]. 地学前缘, 2017, 24(4): 51-56.
[10]	田继先, 曾旭, 易士威, 郭泽清. 咸化湖盆致密油储层“甜点”预测方法研究：以柴达木盆地扎哈泉地区上干柴沟组为例[J]. 地学前缘, 2016, 23(5): 193-201.
[11]	闫德宇,黄文辉,张金川. 鄂尔多斯盆地海陆过渡相富有机质泥页岩特征及页岩气意义[J]. 地学前缘, 2015, 22(6): 197-206.
[12]	吕古贤. 金属矿田地质勘探类型及其评价方案[J]. 地学前缘, 2015, 22(4): 13-21.
[13]	刘殿浩, 吕古贤, 张丕建, 丁正江, 张军进, 林大伟, 马宾. 胶东三山岛断裂构造蚀变岩三维控矿规律研究与海域超大型金矿的发现[J]. 地学前缘, 2015, 22(4): 162-172.
[14]	班超, 郑永春, 张锋, 朱永超, 邹永廖. 月球风暴洋地区元素丰度研究：“嫦娥二号”X射线谱仪探测数据分析[J]. 地学前缘, 2014, 21(6): 62-73.
[15]	凌宗成, 刘建忠, 张江, 李勃, 武中臣, 倪宇恒, 孙灵芝. 基于“嫦娥一号”干涉成像光谱仪数据的月球岩石类型填图: 以月球雨海—冷海地区（LQ-4）为例[J]. 地学前缘, 2014, 21(6): 107-120.