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新生代亚洲季风的演化过程

林旭 吴中海 董延钰 谢远云 刘海金 李兆宁

林旭,吴中海,董延钰,等,2024. 新生代亚洲季风的演化过程[J]. 地质力学学报,30(4):673−690 doi: 10.12090/j.issn.1006-6616.2023093
引用本文: 林旭,吴中海,董延钰,等,2024. 新生代亚洲季风的演化过程[J]. 地质力学学报,30(4):673−690 doi: 10.12090/j.issn.1006-6616.2023093
LIN X,WU Z H,DONG Y Y,et al.,2024. The evolutionary process of Cenozoic Asian monsoon[J]. Journal of Geomechanics,30(4):673−690 doi: 10.12090/j.issn.1006-6616.2023093
Citation: LIN X,WU Z H,DONG Y Y,et al.,2024. The evolutionary process of Cenozoic Asian monsoon[J]. Journal of Geomechanics,30(4):673−690 doi: 10.12090/j.issn.1006-6616.2023093

新生代亚洲季风的演化过程

doi: 10.12090/j.issn.1006-6616.2023093
基金项目: 国家自然科学基金项目(41972212);湖北省楚天学者人才计划(8210403)
详细信息
    作者简介:

    林旭(1984—),男,副教授,主要从事青藏高原隆升、黄河和长江演化研究。Email:hanwuji-life@163.com

    通讯作者:

    董延钰(1986—),男,高级工程师,主要从事第四纪地质学的研究。Email:76000932@qq.com

  • 中图分类号: P534.63

The evolutionary process of Cenozoic Asian monsoon

Funds: This research is financially supported by the National Natural Science Foundation of China (Grant No. 41972212) and the Chutian scholars talent program of Hubei Province (Grant No. 8210403).
  • 摘要: 陆地和海洋热容量差异会引起风向和降水发生季节性反转形成季风气候。亚洲是世界上季风气候最典型的区域,同时也有最多的受季风气候影响的人口。季风带来的强降水容易诱发多种次生灾害,严重影响着区域内人类社会生产、居住的安全,因而认识亚洲季风的形成过程至关重要。利用将古论今的地学思想,文章旨在阐述亚洲季风的组成,列举影响亚洲季风形成、演化的主要因素,总结亚洲关键地点的沉积记录显示的南亚季风和东亚季风的演化期次。结果表明,在古近纪,印度板块与亚洲大陆南缘发生碰撞,改变了亚洲的海陆分布,导致青藏高原发生初始隆升,南亚和东亚均出现季风性气候。但此时的东亚地区依然主要受行星风系的控制,东亚季风处于孕育阶段,仅呈条带状局部分布在华南板块的南缘,而南亚季风的覆盖面积相对广泛。这可能主要是因为东亚地区的边缘海打开时间明显要晚于南亚地区海陆分布出现的时间。但随着青藏高原在中新世整体隆升并接近现今的海拔高度,亚洲季风全面进入增强阶段,强烈影响区域内的地质演化过程。自中新世中期以来,由于受控于青藏高原隆升、南北极冰盖的发育,亚洲季风经历了多期次的稳定发展阶段。研究成果为科学合理利用季风开展亚洲系统地球科学研究提供了参考。

     

  • 图  1  亚洲季风组成分布图(据林旭等,2023修改)

    Figure  1.  Composition distribution map of Asian monsoon (modified after Lin et al., 2023)

    图  2  亚洲季风形成图

    a—亚洲夏季风形成过程图;b—亚洲冬季风形成过程图

    Figure  2.  The formation map of Asian monsoon

    (a) Map showing the formation process of the Asian summer monsoon; (b) Map showing the formation process of the Asian winter monsoon

    图  3  新生代亚洲海陆分布图

    a—始新世;b—渐新世;c—中新世;d—上新世

    Figure  3.  Cenozoic marine and land distribution map in Asia

    (a) Eocene; (b) Oligocene; (c) Miocene; (d) Pliocene

    图  4  新生代青藏高原演化过程图(据Su et al.,2019修改)

    a—古新世—始新世;b—渐新世;c—中新世;d—现今

    Figure  4.  Cenozoic evolutionary process diagram of the Tibetan Plateau (modified after Su et al.,2019)

    (a) Paleocene-Eocene; (b) Oligocene; (c) Miocene ; (d) Present day

    图  5  新生代气候变化特征

    a—新生代全球深海氧同位素曲线(据Zachos et al.,2001修改);b—古新世干旱气候下形成的盐湖;c—始新世干燥气候形成的红层;d—中新世连续性南极冰盖出现;e—上新世晚期—更新世连续性北极冰盖出现

    Figure  5.  Characteristics of Cenozoic climate change

    (a) Cenozoic global deep-sea oxygen isotope curve (modified after Zachos et al.,2001); (b) Salt lakes formed in the arid climate of the Paleocene; (c) The red layer formed in the dry climate of the Eocene; (d) The emergence of a continuous Antarctic ice sheet during the Miocene; (e) The late Pliocene-Pleistocene continuous Arctic ice sheet appeared

    图  6  亚洲季风研究结果位置分布图

    ①Shukla et al.(2014),Bhatia et al.(2021);②Licht et al.(2014),Huang et al.(2023);③Ding et al.(2017);④Fang et al.(2021);⑤Srivastava et al.(2012);⑥Beasley et al.(2021);⑦Clift et al.(2008);⑧Sanyal and Sinha(2010);⑨Clift et al.(2002);⑩Gupta et al.(2015);⑪Betzler et al.(2016),Bretschneider et al.(2021);⑫Gupta et al.(2004);⑬Tripathi et al.(2017);⑭Khan et al.(2019);⑮Cai et al.(2020);⑯Lu et al.(2020);⑰Li et al.(2018a);⑱Dupont-Nivet et al.(2007),Licht et al.(2014);⑲Su et al.(2020);⑳Sorrel et al.(2017),Zheng et al.(2022),Yuan et al.(2024);㉑Lyu et al.(2021);㉒Quan et al.(2011),Meng et al.(2018a);㉓Su et al.(2022);㉔Xie et al.(2020b);㉕Sun et al.(2010);㉖Hellwig et al.(2018);㉗Wang et al.(2020);㉘Lin et al.(2015);㉙Wu et al.(2017);㉚Miao et al.(2013);㉛Yan et al.(2018);㉜Huang and Hinnov(2019);㉝Ren et al.(2021),Vornlocher et al.(2021);㉞Miao et al.(2011);㉟Jacques et al.(2011);㊱Li et al.(2019);㊲Guo et al.(2002);㊳An et al.(2001);㊴Ao et al.(2016);㊵Meng et al.(2018b);㊶Song et al.(2013);㊷Jia et al.(2003),Ding et al.(2021);㊸Wan et al.(2007);㊹Chen et al.(2003),Holbourn et al.(2021);㊺Wang et al.(2003b),Zheng et al.(2004);㊻Wang et al.(2003b);Gai et al.(2020

    Figure  6.  Location distribution of research results of the Asian monsoon

    图  7  新生代南亚和东亚季风演化过程与全球海陆分布、青藏高原隆升和全球气候变化的对应关系(图中数字与图6的位置一一对应,蓝色矩形框的长度代表时间跨度)

    Figure  7.  Correspondence between the evolution of the Cenozoic South Asian and East Asian monsoons and the global land-sea distribution, the uplift of the Tibetan Plateau, and global climate change (The numbers in the figure correspond to the positions in Figure 6; the length of the blue rectangular box represents the time)

    图  8  新生代东亚气候演变过程图(据Guo et al.,2008修改)

    a—始新世气候格局分布图;b—中新世气候格局分布图

    Figure  8.  Climate evolution in East Asia during the Cenozoic era (modified after Guo et al., 2008)

    (a) Eocene climate pattern distribution map; (b) Miocene climate pattern distribution map

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  • 收稿日期:  2023-06-09
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