公元9世纪以来长江潮区界的迁移过程重建

doi:10.7605/gdlxb.2020.06.084

Abstract
Figure/Table
References()
Related Citation (12)
Read Tracking
Download Tracking

Download: PDF (5925 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS) Supporting Info

Abstract The tide can now propagate upstream for more than 600 km from the Changjiang River estuary to hinterland,which is rare in the world. In China,information and records reflecting tidal limit and its movement in the Changjiang River can be found from some ancient books,literary works and local chronicles. At the end of the 3rd and the beginning of the 4th century AD, the tide limit of the Changjiang River reached the upstream of Chaisang(now named Jiujiang in Jiangxi Province). At the early 9th century,the tide limit in the dry season retreated to the Penpukou in Jiujiang. In the last ten years of the 13th century,the tidal limit moved back to the Xiaogushan Mountain near the border between Anhui Province and Jiangxi Province. By the middle of the 20th century,the modern researchers generally agreed that the tidal limit retreated to Datong in Anhui Province. Before the main stream of the Changjiang River was cut off by large-scale water conservancy projects,the tide limit had retreated seaward continuously. From the 3rd decade of the 9th century to the last decade of the 13th century,the tide limit moved downstream 64 km during the 470 years,with an average annual rate of 0.136km/a. During the 670 years from the end of the 13th century to the middle of the 20th century,the tide limit had moved downstream 170 km,with an average annual rate of 0.254 km/a,almost twice as much as that of the previous period. We suggest the climate change accounted for the different retreat rate of the tidal limit between the two periods discussed. In addition,a recent study found that during the extremely dry periods,when the discharge of Jiujiang station was about 8440 m³/s,the tidal limit reached near Jiujiang. In the years when the water conservancy project on the main stream of the Changjiang River began to store water,the tide limit actually returned to the previous position of the middle Tang Dynasty,i.e. 1100 years ago.

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	Zhang Ren-Shun
	Gao Chao
	Wang Ya-Ping

Key words： Changjiang River tide limit Jiujiang Xiaogushan Mountain Datong in Anhui Province

Received: 17 January 2020

ZTFLH:

P512.32

Fund:Co-funded by the National Natural Science Foundation of China(No.41625021)and the Innovation Program of Shanghai Municipal Education Commission(No.2019-01-07-00-05-E00027)

Corresponding Authors: Wang Ya-Ping,born in 1972,professor,Ph.D.,is engaged in research on estuarine and coastal science. E-mail: ypwang@nju.edu.cn.

About author: Zhang Ren-Shun,born in 1940,professor,is engaged in researches on marine geography and dynamic geomorphology.

Cite this article:

Zhang Ren-Shun,Gao Chao,Wang Ya-Ping. Reconstruction of the Changjiang River tidal-limit movement since the ninth century AD[J]. JOPC, 2020, 22(6): 1221-1232.

URL:

http://journal09.magtechjournal.com/gdlxb/EN/10.7605/gdlxb.2020.06.084 OR http://journal09.magtechjournal.com/gdlxb/EN/Y2020/V22/I6/1221

[1] 蔡晓英. 2005. 李绅年谱. 湖北大学硕士学位论文:53-55.
[Cai X Y.2005. A chronicle of Li Kun,s life. Masteral dissertation of Hubei University:53-55]
[2] 长江水利委员会. 1999. 长江流域地图集. 北京: 中国地图出版社,286.
[Changjiang Water Resources Commission. 1999. Atlas of the Yangtze River Basin. Beijing: Sinomap Press,286]
[3] 陈吉余. 1988. 长江河口动力过程和地貌演变. 上海: 上海科学技术出版社,1-454.
[Chen J Y.1988. Dynamic Processes and Geomorphological Evolution of the Yangtze Estuary. Shanghai: Shanghai Science and Technical Publishers,1-454]
[4] 陈吉余,恽才兴. 1959. 南京吴淞间长江河槽的演变过程. 地理学报, 25(3): 221-239.
[Chen J Y,Yun C X.1959. The evolution of the Yangtze river channel between Nanjing and Wusong. Acta Geographica Sinica, 25(3): 221-239]
[5] 侯成程,朱建荣. 2013. 长江河口潮流界与径流量定量关系研究. 华东师范大学学报(自然科学版),(5): 24-32.
[Hou C C,Zhu J R.2013. Study on the quantitative relationship of the location of the tidal current limit and the river discharge in the Changjiang Estuary. Journal of East China Normal University(Natural Science),(5): 24-32]
[6] 师长兴. 2008. 长江上游输沙尺度效应研究. 地理研究, 27(4): 800-810.
[Shi C X.2008. Scaling effects on sediment yield in the upper Yangtze River. Geographical Research, 27(4): 800-810]
[7] 石盛玉,程和琴,玄晓娜,胡方西,袁小婷,姜月华,周权平. 2018. 近十年来长江河口潮区界变动. 中国科学: 地球科学, 48(8): 1085-1095.
[Shi S Y,Cheng H Q,Xuan X N,Hu F X,Yuan X T,Jiang Y H,Zhou Q P.2018. Fluctuations in the tidal limit of the Yangtze River estuary in the last decade. Scientia Sinica Terrae, 48(8): 1085-1095]
[8] 王姝,李金建,秦宁生. 2019. 基于历史帕默尔干旱指数(PDSI)数据集重建的长江源区过去706 a径流量. 中国沙漠, 39(3): 126-135.
[Wang S,Li J J,Qin N S.2019. Runoff Reconstruction for the Source of the Yangtze River over the Past 706 Years Based on Historical PDSI Dataset. Journal of Desert Research, 39(3): 126-135]
[9] 王文才,李一平,杜薇,曾伟峰,许益新. 2017. 长江感潮河段潮汐变化特征. 水资源保护, 33(6): 121-132.
[Wang W C,Li Y P,Du W,Zeng W F,Xu Y X.2017. Tidal variation feature of tidal reach of Changjiang River. Water Resources Protection, 33(6): 121-132]
[10] 汪亚平,潘少明,H.V. Wang,高建华,杨旸,王爱军,李占海,吴中. 2006. 长江口水沙入海通量的观测与分析. 地理学报, 61(1): 35-46.
[Wang Y P,Pan S M,Wang H V,Gao J H,Yang Y,Wang A J,Li Z H,Wu Z.2006. High-resolution measurements and analysis of water discharge and suspended sediment flux in Chanjiang Estuary. Acta Geographica Sinica, 61(1): 35-46]
[11] 熊飞,漆身起,黄顺强. 1994. 谢叠山全集校注. 上海: 华东师范大学出版社,1-203.
[Xiong F,Qi Q S,Huang S Q.1994. Collation and Annotation of the Complete Works of XieDieshan. Shanghai: East China Normal University Press,1-203]
[12] 徐汉兴,樊连法,顾明杰. 2012. 对长江潮区界与潮流界的研究. 水运工程,(6): 15-20.
[Xu H X,Fan L F,Gu M J.2012. On tidal mark and tidal current mark in the Yangtze River. Port & Waterway Engineering,(6): 15-20]
[13] 恽才兴. 2004. 长江河口近期演变基本规律. 北京: 海洋出版社,1-290.
[Yun C Y.2004. The Basic Law of Recent Evolution of Yangtze River Estuary. Beijing: China Ocean Press,1-290]
[14] 邹逸麟,张修桂. 2013. 中国历史自然地理. 北京: 科学出版社, 1-720.
[Zou Y L,Zhang X G.2013. Historical Physical Geography of China. Beijing: Science Press, 1-720]
[15] Cai H,Savenije H H G,Jiang C.2014. Analytical approach for predicting fresh water discharge in an estuary based on tidal water level observations. Hydrology and Earth System Sciences, 18(10): 4153-4168.
[16] Chen F H,Chen J H,Huang W,Chen S Q,Huang X Z,Jin L Y,Jia J,Zhang X J,An C B,Zhang J W,Zhao Y,Yu Z C,Zhang R H,Liu J B,Zhou A F,Feng S.2019. Westerlies Asia and monsoonal Asia: Spatiotemporal differences in climate change and possible mechanisms on decadal to sub-orbital timescales. Earth-Science Reviews, 192: 337-354.
[17] Ding Y H,Chan J C.2005. The East Asian summer monsoon: An overview. Meteorology and Atmospheric Physics, 89(1): 117-142.
[18] Godin G.1985. Modification of river tides by the discharge. Journal of Waterway,Port,Coastal,and Ocean Engineering, 111(2): 257-274.
[19] Godin G.1991. Frictional effects in river tides. Tidal Hydrodynamics, 379: 402.
[20] Godin G.1999. The propagation of tides up rivers with special considerations on the upper Saint Lawrence River. Estuarine,Coastal and Shelf Science, 48(3): 307-324.
[21] Horrevoets A C,Savenije H H G,Schuurman J N,Graas S.2004. The influence of river discharge on tidal damping in alluvial estuaries. Journal of Hydrology(Amsterdam), 294(4): 223-228.
[22] IPCC(Intergovernmental Panel on Climate Change). 2007. Climate change 2007: The physical science basis. In: Working Group I Contribution to the Fourth Assessment Report of the IPCC. Cambridge,UK: Cambridge University Press, 95-123.
[23] Jay D A,Flinchem E P.1997. Interaction of fluctuating river flow with a barotropic tide: A demonstration of wavelet tidal analysis methods. Journal of Geophysical Research,102(C3): 5705.
[24] Milliman J D,Farnsworth K L.2013. River Discharge to the Coastal Ocean: A Global Synthesis. Cambridge,UK: Cambridge University Press, 289-311.
[25] Wang Y J,Cheng H,Edwards R L,He Y Q,Kong X G,An Z S,Wu J Y,Kelly M J,Dykoski C A,Li X D.2005. The Holocene Asian monsoon: Links to solar changes and North Atlantic climate. Science, 308(5723): 854-857.
[26] Wang Z H,Li M T,Zhang R H,Zhuang C C,Liu Y,Saito Y,Xie J L,Zhao B C.2011. Impacts of human activity on the late-Holocene development of the subaqueous Yangtze delta,China,as shown by magnetic properties and sediment accumulation rates. The Holocene, 21(3): 393-407.
[27] Wang Z H,Saito Y,Zhan Q,Nian X M,Pan D D,Wang L,Chen T,Xie J L,Li X,Jiang X Z.2018. Three-dimensional evolution of the Yangtze River mouth,China during the Holocene: Impacts of sea level,climate and human activity. Earth-Science Reviews, 185: 938-955.
[28] Yang S L,Zhao Q Y,Belkin I M.2002. Temporal variation in the sediment load of the Yangtze River and the influences of the human activities. Journal of Hydrology, 263: 56-71.
[29] Zhao Y F,Zou X Q,Liu Q,Yao Y L,Li Y L,Wu X W,Wang C L,Yu W W,Wang T.2017. Assessing natural and anthropogenic influences on water discharge and sediment load in the Yangtze River,China. Science of the Total Environment, 607-608: 920-932.