长江口盐水入侵对海平面上升的响应特征

陈维; 匡翠萍; 顾杰; 贺露露

doi:10.16198/j.cnki.1009-640X.2018.01.009

长江口盐水入侵对海平面上升的响应特征

doi: 10.16198/j.cnki.1009-640X.2018.01.009

陈维^1,,
匡翠萍^2, ,,
顾杰³,
贺露露⁴

1.
浙江海洋大学港航与交通运输工程学院, 浙江舟山 316022
2.
同济大学土木工程学院, 上海 200092
3.
上海海洋大学海洋科学学院, 上海 201306
4.
浙江工业大学建筑工程学院, 浙江杭州 310014

基金项目:

国家重点基础研究发展计划(973计划)资助项目 2012CB957704

详细信息

作者简介:
陈维(1987—), 女, 湖南常德人, 讲师, 博士, 主要从事港口、海岸及近海工程研究。E-mail: chenwei_112233@163.com

通讯作者:
匡翠萍(E-mail: cpkuang@tongji.edu.cn)

中图分类号: P343.5

Responses of saline water intrusion to sea level rise in the Yangtze Estuary

CHEN Wei^1
,,
KUANG Cuiping^{2
, ,},
GU Jie³,
HE Lulu⁴

1.
College of Port and Transportation Engineering, Zhejiang Ocean University, Zhoushan 316022, China
2.
College of Civil Engineering, Tongji University, Shanghai 200092, China
3.
College of Marine Sciences, Shanghai Ocean University, Shanghai 201306, China
4.
College of Civil Engineering and Architecture, Zhejiang University of Technology, Hangzhou 310014, China

摘要: 基于MIKE3软件建立了潮流作用下长江口三维水动力及盐度输运数学模型, 采用实测潮位、流速、流向以及盐度资料对模型进行了验证。运用验证好的数学模型对海平面上升后长江口枯季盐水入侵进行了模拟, 从而分析海平面上升条件下长江口枯季盐水入侵的响应特征, 得出以下结论：海平面上升1 m后, 北支上段、南支、南北港以及南北槽的盐度均上升, 南支平均盐度均超过0.45 psu, 北支中下段的盐度却明显减小；海平面上升后潮汐的作用更强, 北支下段底层层化现象减弱, 北支径流动力增强, 表层层化现象增强, 表层Richardson数达150；南槽Richardson数底部减小, 表层增大, 但垂直结构趋势变化不明显。
- 长江口 /
- 盐水入侵 /
- 海平面上升 /
- MIKE3 /
- Richardson数
Abstract: A 3D numerical model of hydrodynamic and salinity transport of the Yangtze Estuary under the influence of tide is established based on MIKE3 software. This model is validated with the field measured tidal level, flow velocity, flow magnitude and salinity. The validated model is used to simulate the saline water intrusion caused by sea level rise (SLR) in the Yangtze Estuary in the dry season. The responses of saline water intrusion to SLR in the Yangtze Estuary are analyzed. The results indicate that: the salinity in the upper reach of the North Branch, the South Branch, the North Channel, the South Channel, the North Passage and the South Passage obviously increase due to 1 meter of the SLR, especially when the average salinity of the South Branch entirely exceeds 0.45 psu, however it decreases significantly in the lower reach of the North Branch. This is induced by the increased flow split ratio of the North Branch due to SLR. The greater flood tidal current and flow split ratio of the North Branch due to SLR make stratification phenomenon of salinity increase with the Richardson number reaching 150 in the surface layer. For the South Passage, the bottom stratification phenomenon is weakened and the surface stratification phenomenon is enhanced, however the vertical trend is not apparent.
- the Yangtze Estuary /
- saline water intrusion /
- sea level rise /
- MIKE3 software /
- Richardson number
图 1 站点及断面位置

Figure 1. Positions of stations and sections

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图 2 计算区域及网格

Figure 2. Computational region and grid

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图 3 潮位验证过程

Figure 3. Verification of tidal level

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图 4 流速流向验证

Figure 4. Verification of flow magnitude and direction

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图 5 盐度验证

Figure 5. Verification of salinity

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图 6 原海平面及上升1 m情形下涨憩时刻盐度的平面分布(单位：psu)

Figure 6. Depth-averaged salinity at flood slack at primary sea level (PSL) and 1 m of sea level rise (SLR) scenarios (unit: psu)

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图 7 原海平面及上升1 m情形下北支下段河道纵剖面(D1)上的盐度垂向分布

Figure 7. Vertical salinity of the North Branch at PSL and 1 m of SLR scenarios

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图 8 原海平面及上升1 m情形下北支下段AA1点的Richardson数垂向分布

Figure 8. Vertical Richardson number at point AA1 of the North Branch at PSL and 1 m of SLR scenarios

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图 9 原海平面及上升1 m情形下南支、南港和南槽河道纵剖面(D2)上的盐度垂向分布

Figure 9. Vertical salinity of the South Branch, South Channel and South Passage at PSL and 1 m of SLR scenarios

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图 10 原海平面及上升1 m情形下南槽AA2点的Richardson数垂向分布

Figure 10. Vertical Richardson number at point AA2 of the South Passage at PSL and 1 m of SLR scenarios

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长江口盐水入侵对海平面上升的响应特征

doi: 10.16198/j.cnki.1009-640X.2018.01.009

作者简介: 陈维(1987—), 女, 湖南常德人, 讲师, 博士, 主要从事港口、海岸及近海工程研究。E-mail: chenwei_112233@163.com

通讯作者: 匡翠萍(E-mail: cpkuang@tongji.edu.cn)

Responses of saline water intrusion to sea level rise in the Yangtze Estuary

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出版历程

作者简介:
陈维(1987—), 女, 湖南常德人, 讲师, 博士, 主要从事港口、海岸及近海工程研究。E-mail: chenwei_112233@163.com

通讯作者:
匡翠萍(E-mail: cpkuang@tongji.edu.cn)