Spatio-temporal characteristics and causes of changes in erosion-accretion in the Yangtze (Changjiang) submerged delta from 1982 to 2010

doi:10.1007/s11442-015-1209-4

地理学报(英文版) ›› 2015, Vol. 25 ›› Issue (8): 899-916.doi: 10.1007/s11442-015-1209-4

• • 下一篇

收稿日期:2014-12-20 接受日期:2015-01-25 出版日期:2015-08-15 发布日期:2015-07-17

Spatio-temporal characteristics and causes of changes in erosion-accretion in the Yangtze (Changjiang) submerged delta from 1982 to 2010

Chengcheng SONG^1,²(), Xiaojing SUN³, Jun WANG^1,^2,^*(), Mengya LI^1,², Lu ZHENG^1,²

1. School of Geographic Sciences, East China Normal University, Shanghai 200241, China
2. Key Laboratory of Geographic Information Science of Ministry of Education, East China Normal University, Shanghai 200241, China
3. Department of Chemistry, East China Normal University, Shanghai, 200241, China

Received:2014-12-20 Accepted:2015-01-25 Online:2015-08-15 Published:2015-07-17
Contact: Jun WANG E-mail:songchengcheng2008@163.com;jwang@geo.ecnu.edu.cn
About author:
Author: Song Chengcheng (1991-), specialized in assessment of coastal disaster risk. E-mail:songchengcheng2008@163.com
Supported by:
National Natural Science Foundation of China, No.71373084;Global Change Scientific Research Program of China, No.2010CB951204;Innovation Program of Shanghai Municipal Education Commission, No.13ZZ035

摘要/Abstract

Abstract:

The Yangtze delta’s response to accelerating river damming and irrigation is a topic of global concern. This research analyzed the general erosion-accretion of the submerged delta front, the spatio-temporal changing pattern in different sub-regions, the geomorphological changes in typical cross-sections, and the geomorphological causes of the four main sub-regions (the eastern tidal wetland of Chongming-CM, the Hengsha shoal-HS, the Jiuduansha wetland-JDS, and the eastern tidal wetland of Nanhui-NH). Data sources include topographic data measured at high-resolution, sediment load at Datong Station, and the corresponding estuary construction information. Major findings are: (1) in general, the study area had slightly eroded (the erosion area ratio was 51.83% and the accretion area ratio was 48.17%) from 1982 to 2010, and it had experienced a shift of “erosion-accretion- erosion”. The spatio-temporal change of geomorphology was also significant in the eight sub-regions, excluding constant erosion in the North Channel; (2) evolution in eastern and northern CM and HS, northern JDS, and the region within the 5 m isobath of NH was dominated by vertical deposition, which was the opposite of that in southern CM and HS, and the region within the 5 m isobath of eastern and southern JDS; (3) on the whole, the encompassed surface areas (ESAs) of the 2 m and 5 m isobaths kept increasing, and the annual growth rates reached 10.42 km²/yr and 7.99 km²/yr respectively during 1982-2010 (however, four sub-regions exhibited disagreements), and in the whole region and all sub-regions, the ESA of the 10 m isobath decreased, while the ESA of the 15 m isobath changed slightly during the period and remained stable; (4) being less influenced by the estuarine engineering, CM was the only sub-region where the ESA of the isobath decreased in accordance with the decline of the sediment load. Major conclusions are that estuarine engineering projects play an increasingly important role in affecting the submerged delta against the macro-background of the reduction of sediment load, the change of ESA and the distribution of isobaths. Along with the accelerating construction of the Shanghai International Shipping Centre and reclamation project, the geomorphological evolution of the submerged delta will become more complex and thus deserves frequent monitoring in the future.

Key words: erosion-accretion changes, spatio-temporal characteristics, causes, submerged delta, Yangtze (Changjiang) Estuary, China

. [J]. 地理学报(英文版), 2015, 25(8): 899-916.

Chengcheng SONG, Xiaojing SUN, Jun WANG, Mengya LI, Lu ZHENG. Spatio-temporal characteristics and causes of changes in erosion-accretion in the Yangtze (Changjiang) submerged delta from 1982 to 2010[J]. Journal of Geographical Sciences, 2015, 25(8): 899-916.

图/表 12

参考文献 37

1	Adrain S, Sebastian D, Viorel G U, 2007. Coastal changes at the Sulina mouth of the Danube River as a result of human activities.Marine Pollution Bulletin, 55: 555-563.
2	Anfuso G, DelPozo J A M, 2005. Towards management of coastal erosion problems and human structure impacts using GIS tools: Case study in Ragusa Province, Southern Sicily, Italy.Environmental Geology, 48: 646-659.
3	Bao Q F, Ren G H, 2013. Strategy research on urban new space development and new deepwater port in Hengsha.Engineering Science, 15(6): 14-19.
4	Blum M D, Roberts H H, 2009. Drowning of the Mississippi Delta due to insufficient sediment supply and global sea-level rise.Nature Geoscience, 2: 488-491.
5	Carriquiry J D, Sánchez A, Camacho-Ibar V F, 2001. Sedimentation in the northern Gulf of California after cessation of the Colorado River discharge.Sedimentary Geology, 144(1/2): 37-62.
6	Chen J Y, 1988. Comprehensive Survey Report of the Coastal Zone and Tidal Land Resources in 1982. Shanghai: Shanghai Science and Technology Press. (in Chinese)
7	Chen J Y, Zhu H F, Dong Y Fet al., 1985. Development of the Changjiang Estuary and its submerged delta.Continental Shelf Research, 4(1/2): 47-56.
8	Chen X, Zhang E, Mu Het al., 2005. A preliminary analysis of human impacts on sediment loads from the Yangtze, China, into the sea.Journal of Coastal Research, 21(3): 515-521.
9	Cui BL, Li XY, 2011. Coastline change of the Yellow River Estuary and its response to the sediment and runoff (1976-2005).Geomorphology, 127: 32-40.
10	Dai Z J, Liu J T, Fu Get al., 2013. A thirteen-year record of bathymetric changes in the North Passage, Changjiang (Yangtze) Estuary. Geomorphology, 187: 101-107.
11	Ding P X, Li S G, 2013. Planning ideas and key technology for building excavated-in harbor basin in the Hengsha Shoal of the Yangtze Estuary.Journal of East China Normal University: Natural Science, (4): 1-9. (in Chinese)
12	Fan D D, Kuang C P, Liu S Get al., 2013. Impacts of mega-engineers in Changjiang River catchment on coastal land reclamation and wetland conservation.Journal of Tongji University: Natural Science, 41(3): 458-464. (in Chinese)
13	Fanos A M, 1995. The impact of human activities on the erosion and accretion of the Nile delta coast.Journal of Coastal Research, 11: 821-833.
14	Finkl C W, 1994. Coastal hazards: Perception, susceptibility and mitigation.Journal of Coastal Research, 12(Special Issue): 372.
15	Frihy O E, Dewidar K M, 2003. Pattern of erosion/sedimentation, heavy mineral concentration and grain size to interpret boundaries of littoral sub-cells of the Nile Delta, Egypt.Marine Geology, 199: 27-43.
16	Hayashi S J, Murakami S G, Xu K Qet al., 2008. Effect of the Three Gorges Dam Project on flood control in the Dongting Lake area, China, in a 1998-type flood.Journal of Hydro-environment Research, 2: 148-163.
17	Hu H B, Zhan Y L, 2011. Visualization of river channel evolution of the South Branch in Yangtze Estuary supported by GIS.Procedia Environmental Sciences, 10: 1899-1903.
18	Ji N, Cheng H Q, Yang Z Yet al., 2013. Sedimentary and morphological evolution of nearshore coast of Yangtze Estuary in the last 30 years.Acta Geographica Sinica, 68(7): 945-954. (in Chinese)
19	Kuang C P, Liu X, Gu Jet al., 2013. Numerical prediction of medium-term tidal flat evolution in the Yangtze Estuary: Impacts of the Three Gorges project.Continental Shelf Research, 52: 12-26.
20	Li P, Yang S L, Dai S Bet al., 2007. Accretion/erosion of the subaqueous delta at the Yangtze Estuary in recent 10 years.Acta Geographica Sinica, 62(7): 708-714. (in Chinese)
21	Liu Y Y, Zhang X N, Xu S Qet al., 2010. Analysis on erosion-deposition of foreshore landforms of the Yangtze River Estuary.Resources and Environment in the Yangtze Basin, 19(11): 1314-1321. (in Chinese)
22	Lu X X, Higgitt DI, 2001. Sediment delivery to the Three Gorges 2: Local response.Geomorphology, 41: 157-169.
23	Milliman J D, 1997. Blessed dams or damned dams?Nature, 388: 325-326.
24	Milliman J D, Farnsworth K L, 2011. River Discharge to the Coastal Ocean: A Global Synthesis. New York: Cambridge University Press.
25	Nilsson C, Reidy C A, Dynesius Met al., 2005. Fragmentation and flow regulation of the world’s large river systems.Science, 308: 405-408.
26	Syvitski J P, Kettner A J, Overeem Iet al., 2009. Sinking deltas due to human activities.Nature Geoscience, 2: 681-686.
27	Trenhaile A S, 1997. Coastal Dynamics and Landforms. Oxford: Clarendon, pp.365.
28	Wan Y Y, Gu F F, Wu H Let al., 2014. Hydrodynamic evolutions at the Yangtze Estuary from 1998 to 2009.Applied Ocean Research, 47: 291-302.
29	Wang Y H, Ridd P V, Wu H Let al., 2008. Long-term morphodynamic evolution and the equilibrium mechanism of a flood channel in the Yangtze Estuary (China).Geomorphology, 99: 130-138.
30	Xie W H, Yang S L, 1999. Evolution of the Jiuduansha shoal and its influence on adjacent channels in the Changjiang Estuary.China Ocean Engineering, 13(2): 185-195.
31	Yang S L, 1999. A study of coastal morphodynamics on the Muddy Islands in the Changjiang River Estuary.Journal of Coastal Research, 15(1): 32-44.
32	Yang S L, Belkin I M, Belkina A Iet al., 2003. Delta response to decline in sediment supply from Yangtze River: Evidence of the recent four decades and expectations for the next half-century.Estuarine, Coastal and Shelf Science, 57: 689-699.
33	Yang S L, Milliman J D, Li Pet al., 2011. 50000 dams later: Erosion of the Yangtze River and its delta.Global and Planetary Change, 75: 14-20.
34	Yang S L, Zhang J, Zhu Jet al., 2005. Impact of dams on Yangtze River sediment supply to the sea and delta wetland response.Journal of Geophysical Research, 110. doi: 10.1029/2004JF000271.
35	Yu Z Y, Zhang Z L, Jin Let al., 2013. Morphological stability analysis of the planned excavated-in harbor and its channel in the Hengsha Shoal of the Yangtze Estuary. Journal of East China Normal University (Natural Science), (4): 55-71. (in Chinese)
36	Yun C X, 1983. Scouring and siltation processes of tidal flats of the Yangtze River Estuary and sediment exchange between flats and channels.Journal of Sediment Research, (4): 43-45. (in Chinese)
37	Yun C X, 2004. Recent Developments of the Changjiang Estuary. Beijing: China Ocean Press. (in Chinese)

Indicators/periods	1982-2010	1982-1997	1997-2002	2002-2010
Area ratio of accretion and erosion zones	0.92	0.90	1.14	1.05
Net erosion-accretion quantity (10⁸ m³/yr)	-0.54	-1.26	0.74	-0.01
Net erosion-accretion rate (cm/yr)	-1.11	-2.56	1.50	-0.02
Accretion area (10⁸ m²)	23.66	23.32	26.21	25.18
Accretion volume (10⁸ m³)	41.98	31.02	28.01	30.96
Erosion area (10⁸ m²)	25.46	25.80	22.92	23.96
Erosion volume (10⁸ m³)	57.25	49.93	24.32	31.02

Indicators Areas/periods	Net erosion-accretion quantity (10⁸ m³)				Net erosion-accretion rate (cm/yr)
Indicators Areas/periods	1982-2010	1982-1997	1997-2002	2002-2010	1982-2010	1982-1997	1997-2002	2002-2010
① NB	1.91	-0.76	1.35	1.32	3.11	-2.32	12.31	7.52
② SB	-6.40	-4.87	0.65	-2.18	-4.63	-6.57	2.60	-5.46
③ NC	-4.70	-2.99	-0.76	-0.94	-10.57	-12.57	-9.41	-7.27
④ SC	-1.36	0.79	-0.83	-1.32	-2.52	2.72	-8.47	-8.42
⑤ CM	-4.53	-11.28	5.85	0.89	-1.31	-6.07	9.45	0.90
⑥ HS	-0.52	-2.91	-1.71	4.10	-0.22	-2.36	-4.13	6.19
⑦ JDS	-0.18	1.90	-0.35	-1.73	-0.09	1.86	-1.02	-3.14
⑧ NH	0.83	1.41	-0.56	-0.02	0.27	0.86	-1.03	-0.03

Year	Total area (km²)				Change rate (km²/yr)
Year	1982	1997	2002	2010	1982-1997	1997-2002	2002-2010
The area within 2 m isobath	526.29	607.93	609.88	818.12	5.44	0.39	26.03
The area within 5 m isobath	1685.09	1657.73	1712.27	1808.22	-1.82	10.91	11.99
The area within 10 m isobath	/	3938.22	3883.00	3693.94	/	-11.04	-23.63
The area within 15 m isobath	/	4856.77	4724.45	4765.91	/	-26.46	5.18

Spatio-temporal characteristics and causes of changes in erosion-accretion in the Yangtze (Changjiang) submerged delta from 1982 to 2010

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

图/表 12

参考文献 37

相关文章 0

Metrics

本文评价

推荐阅读 0