Effects of coastal engineering and biological invasion on changes in the coastal pattern of Nanhui Dongtan, Shanghai

doi:10.3969/j.issn.1000-5641.2023.03.016

Abstract

Abstract:

Under the dual influence of human activities and natural factors, the coastal zone patterns are prone to rapid changes which can directly or indirectly affect the structure, function, and sustainable development of the coastal ecosystem. Using the coastal zone of Nanhui Dongtan in Shanghai as a typical research area, we used remote sensing interpretation, sea chart digitization, and field investigation to analyze changes in spatial patterns and changes in coastal zones over the last 20 years (from 2000 to 2020). In addition, the effects of coastal engineering (including reclamation engineering and siltation promotion engineering) and S. alterniflora invasion on coastal pattern dynamics were analyzed. The results showed that: ① Since 2000, under the influence of coastal engineering and biological invasion, the land use types of Nanhui Dongtan coastal zone changed from a simple pattern dominated by coastal wetlands to a complex pattern which included multiple land use types (i.e. coastal wetlands, inland wetlands, constructed wetlands, farmland, and construction land). ② Coastal reclamation engineering decreased 11894.7 hm² of coastal wetlands in the Nanhui Dongtan coastal zone from 2000 to 2005. The reclaimed coastal wetlands were transferred into land use types such as rice fields, ponds, and farmland due to human activities; the reclamation engineering promoted deposition of sediment in the estuary and tidal mudflat (above 0 m) and the intertidal salt marsh developed with increased rates of 320.5 hm²/a and 110.9 hm²/a, respectively; meanwhile, the siltation rate decreased to 286.8 hm²/a and 15.7 hm²/a, respectively, after 2015. After 10 years (2005—2015) of natural recovery, the area of coastal wetlands did not reach the levels seen before reclamation in Year 2000. ③ Two types of siltation promotion engineering—hard siltation promotion engineering and biological siltation promotion engineering—have both significantly promoted the rapid development of coastal wetlands in Nanhui Dongtan. Hard silting promotion engineering with propagation rates of 516.9 hm²/a in tidal mudflats (above 0 m) and 915.7 hm²/a in intertidal salt marshes, respectively, was 5.4 times and 13.9 times higher than rates observed in non-siltation areas; hence, the effects were more significant than biological siltation promotion engineering which only resulted in pattern changes in a limited area between the seawall and the wave dissipation dike by planting S. alterniflora. ④ After introducing S. alterniflora in Nanhui Dongtan, it became the most dominant plant in the Nanhui Dongtan salt marsh, accounting for 56% of the total area; this significantly changed the ecological structure and function of coastal wetlands in 2020. Coastal engineering and biological invasion have a great impact on coastal zone patterns. Although the coastal ecosystem showed a certain resilience to coastal human activities, changes in the wetland type, area, and function were difficult or impossible to recover at a great cost in the future. How to integrate the ecological functions of coastal wetlands and inland wetlands through the implementation of coastal zone restoration, ecological protection, and other measures to achieve the sustainable and healthy development of coastal zones is an important problem for future land and sea planning.

Key words: coastal zone, pattern change, coastal engineering, biological invasion, Nanhui Dongtan

CLC Number:

Tingyu ZHANG, Lin YUAN, Chao ZHANG, Yang LI, Zhiyuan ZHAO, Yuxiao SHI, Liquan ZHANG, Jinghua GU. Effects of coastal engineering and biological invasion on changes in the coastal pattern of Nanhui Dongtan, Shanghai[J]. Journal of East China Normal University(Natural Science), 2023, 2023(3): 167-180.

Figures/Tables 9

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年份	总体精度/%	Kappa 系数
2000	95.5	0.9298
2005	96.7	0.9516
2010	94.4	0.9205
2015	93.5	0.9071
2020	95.2	0.9326

年份	近海与海岸湿地面积/ hm²		内陆湿地面积/ hm²	人工湿地面积/ hm²		非湿地面积/ hm²
年份	淤泥质海滩	潮间盐水沼泽	草本沼泽	库塘	水稻田	农田	建设用地
2000	10969.8	3948.2
2005	3023.3		4066.2	5152.6		1438.2	688.4
2010	4625.6	554.6	3369.7	1747.5	3785.7	1166.9	1302.1
2015	6059.6	632.9	2326.8	1943.4	3949.7	1394.5	1794.5
2020	8643.7	5211.6	3332.2	3453.9	2715.9	1272.2	1989.9

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