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人类活动和自然演变共同驱动下黄河三角洲海域潮波及物质输运变化

缪红兵 乔璐璐 仲毅 李广雪

缪红兵,乔璐璐,仲毅,等. 人类活动和自然演变共同驱动下黄河三角洲海域潮波及物质输运变化[J]. 海洋学报,2022,44(9):73–86 doi: 10.12284/hyxb2022071
引用本文: 缪红兵,乔璐璐,仲毅,等. 人类活动和自然演变共同驱动下黄河三角洲海域潮波及物质输运变化[J]. 海洋学报,2022,44(9):73–86 doi: 10.12284/hyxb2022071
Miao Hongbing,Qiao Lulu,Zhong Yi, et al. Evolution of tidal system and material transport off the Huanghe River Delta induced by human activities and natural evolution[J]. Haiyang Xuebao,2022, 44(9):73–86 doi: 10.12284/hyxb2022071
Citation: Miao Hongbing,Qiao Lulu,Zhong Yi, et al. Evolution of tidal system and material transport off the Huanghe River Delta induced by human activities and natural evolution[J]. Haiyang Xuebao,2022, 44(9):73–86 doi: 10.12284/hyxb2022071

人类活动和自然演变共同驱动下黄河三角洲海域潮波及物质输运变化

doi: 10.12284/hyxb2022071
基金项目: 国家重点研发计划政府间国际科技创新合作重点专项(2017YFE0133500)
详细信息
    作者简介:

    缪红兵(1994-),男,云南省会泽县人,研究方向为海洋沉积动力学。E-mail:mhb@stu.ouc.edu.cn

    通讯作者:

    乔璐璐(1981-),教授,主要从事海洋沉积动力学研究。E-mail:qiaolulu126@sina.com

  • 中图分类号: P343.5;P731.23

Evolution of tidal system and material transport off the Huanghe River Delta induced by human activities and natural evolution

  • 摘要: 在海堤建设等人类活动和三角洲蚀淤等自然演变的共同作用下,黄河三角洲岸线水深近年来发生了剧烈变化,同时也将引起邻近海域潮波系统及物质输运路径的重要变化。本文基于FVCOM数值模式,建立了黄河三角洲及邻近海域三维高分辨率潮汐、潮流及拉格朗日粒子追踪数值模型。通过与环渤海长期验潮站的潮汐调和常数、黄河三角洲临时潮位站和测流站的实测资料对比,模型结果验证良好,能较好反映黄河三角洲及邻近海域潮汐、潮流运动特征,并获得了2019年M2分潮无潮点位置。通过设置1980年、2019年黄河三角洲岸线自然演变、海堤建设及相应水深地形变化的5个数值实验,结果表明:在人类活动与自然演变共同驱动下,黄河三角洲海域的M2分潮无潮点向东南方向移动,主要影响因素为水深。黄河口向海延伸和海堤丁坝建设导致的岸线变化,对无潮点位置影响较小,但在该凸出岸段两侧形成余流流涡,使得黄河入海物质在莱州湾内停留时间变长,向渤海输运扩散的时间推迟。
  • 图  1  渤海2019年水深地形(a)及黄河三角洲1980–2019年水深变化(b)

    Fig.  1  Water depth in the Bohai Sea in 2019 (a) with its variation off the Huanghe River Delta from 1980 to 2019 (b)

    图  2  2019年模式水平网格分布

    Fig.  2  Horizontal model grids in the 2019 situation

    图  3  2019年孤东验潮站水位验证

    Fig.  3  Water level validation of Gudong tide station in 2019

    图  4  KD站位M2、K1分潮潮流椭圆验证

    Fig.  4  Tidal current ellipses validation at KD station for M2 and K1 tidal components

    图  5  KD站位海流验证

    Fig.  5  Current validation at KD station

    图  6  M2分潮无潮点位置迁移示意图

    Fig.  6  The migration of amphidromic points of M2 tidal component

    图  7  M2分潮振幅、迟角变化

    填色代表振幅变化,等值线代表迟角(单位:(°))变化

    Fig.  7  The change of co-amplitude and co-phase lines of the M2 tidal component

    Shaded areas indicate the amplitude change and isolines indicate the phase (unit: (°)) change

    图  8  敏感实验同潮图及无潮点位置

    实线表示迟角(单位:(°));虚线表示振幅(单位:m)

    Fig.  8  Sensitivity experiment co-tidal diagram and amphidromic points position

    The solid lines represent phase (unit: (°)); the dash lines represent amplitude (unit: m)

    图  9  大潮期涨急时刻流速变化

    Fig.  9  Changes of maximum ebb current velocity during spring tide

    图  10  1980年(a)和2019(b)年表层潮余流场

    Fig.  10  Surface tidal residual current field in 1980 (a) and 2019 (b)

    图  11  1980年(a)和2019年(b)切变锋特征

    线条表示切变锋的锋面,数字表示其在两个潮周期内出现的时间(单位:h)

    Fig.  11  Shear front characteristics in 1980 (a) and 2019 (b)

    The lines represent the shear fronts, and the numbers represent the time (unit: h) it occurs over two tidal cycles

    图  12  1980年(a)和2019年(b)拉格朗日粒子示踪结果

    Fig.  12  Lagrangian particle tracer results in 1980 (a) and 2019 (b)

    图  13  基于Landsat的 1980年(a)和2019年(b)黄河三角洲表层悬沙遥感影像,丁坝附近海域的表层悬沙分布(c)和涨潮流场(d)

    Fig.  13  Landsat images of surface suspended sediment off the Huanghe River Delta in 1980 (a) and 2019 (b), distribution characteristics of surface suspended sediment in the sea in front of the dykes (c), and ebb tidal current around the dyke area (d)

    表  1  M2、S2、K1、O1 分潮模拟结果验证

    Tab.  1  Model validation for harmonic constants of M2, S2, K1, O1 tidal components

    验潮站M2S2O1K1
    振幅
    差/cm
    迟角
    差/(°)
    振幅
    差/cm
    迟角
    差/(°)
    振幅
    差/cm
    迟角
    差/(°)
    振幅
    差/cm
    迟角
    差/(°)
    15.595.820.387.26 2.7510.24 0.9115.52
    24.360.501.036.990.590.271.193.80
    30.986.451.580.581.613.400.645.68
    41.753.842.693.330.861.991.110.18
    50.055.492.676.660.042.103.702.20
    65.582.741.038.762.257.493.123.19
    70.560.101.6815.862.083.604.860.51
    85.453.652.173.420.891.263.1810.87
    93.771.800.8811.330.011.051.400.02
    101.454.050.725.881.050.162.360.58
    110.393.130.280.152.982.195.502.51
    121.240.670.471.591.613.712.583.06
    138.068.631.3613.364.202.135.780.76
    142.344.440.833.210.506.542.584.99
    154.567.421.076.484.311.105.042.83
    163.233.600.943.970.596.491.622.65
    1710.150.972.601.420.114.854.163.22
    189.508.001.544.931.612.970.601.29
    190.580.220.542.470.082.471.268.12
    200.434.391.055.810.5810.901.249.12
    216.895.430.4110.470.918.641.323.97
    224.826.841.153.401.618.121.967.15
    孤东04.240.0122.8103.840.010.35
    BH0203.8201.580.033.970.011.18
    平均绝
    对误差
    3.414.011.136.321.304.152.343.91
    下载: 导出CSV

    表  2  数值实验设置及目的

    Tab.  2  Setting and purpose of numerical experiments

    实验水深岸线实验目的
    12019年2019年现状水动力(基准模拟)
    22019年2019年无丁坝丁坝的影响
    31980年2019年黄河三角洲岸线
    水深变化的影响
    41980年黄河三角洲1980年岸线,
    2019年渤海其余岸线
    黄河三角洲
    岸线水深变化的影响
    51980年1980年渤海岸线水深变化的影响
    下载: 导出CSV

    表  3  孤东验潮站2005和2019年主要分潮调和常数

    Tab.  3  Harmonic constants of major components at Gudong tide station in 2005 and 2019

    年份O1分潮K1分潮 M2分潮 S2分潮
    振幅/cm迟角/(°)振幅/cm迟角/(°) 振幅/cm迟角/(°) 振幅/cm迟角/(°)
    2005年19113 23167 10291 57
    2019年19104 24154 3262 3337
    差值0–9 1–13 –7–29 –2–30
    下载: 导出CSV
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  • 收稿日期:  2021-08-22
  • 修回日期:  2022-01-10
  • 网络出版日期:  2022-04-12
  • 刊出日期:  2022-08-29

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