| Qingdao Institute of marine geology, China Geological Survey | Host |
| Citation: |
XU Hehe, LIU Surui, CHEN Jianbin, WANG Houjie, BI Naishuang, YU Yongqing, WANG Yamei, WU Xiao. Variations of hydrological characteristics off the Yellow River Estuary induced by the “7·20” rainstorm flood in Henan Province[J]. Marine Geology Frontiers, 2025, 41(2): 78-91. doi: 10.16028/j.1009-2722.2024.025
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Variations of hydrological characteristics off the Yellow River Estuary induced by the “7·20” rainstorm flood in Henan Province
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Abstract
The frequency and intensity of extreme weather events such as extreme rainstorm floods have been increasing significantly with the global warming. Rainstorm floods could not only have profound impacts on both human society and the natural environment, but also change the fluxes of terrestrial materials to the sea, causing the diffusion path and range of water flow and sediment, which is very significant for the evolution of estuaries. An extraordinary rainstorm event occurred in Zhengzhou, Henan on July 17-23, 2021, causing severe flooding in the lower reaches of the Yellow River. Based on measurement data and satellite remote sensing, we discussed the hydrological characteristics, stratification structure, and dynamic mechanism of the Yellow River Estuary before and after the flood and in the early and late stages. Results show that the average daily runoff at Lijin station was 1.95×108 m3 and the sediment transport amounted to 1.58×106 t during the flood, which is 2.71 times and 9.38 times of that in non-flood period, respectively. Since the duration of high flow and flood cycle were shorter than those during the period of the water-sediment regulation scheme (WSRS), the runoff and sediment flux into the sea during this rainstorm flood is slightly lower than that of the WSRS. Moreover, the turbidity and salinity of the Yellow River estuary changed significantly during the flood, which were associated with the enormous water and sediment discharge of the Yellow River. The turbidity increased obviously and the range of high turbidity zone became wider. In addition, diluted water expanded to the surface to the northwest and southeast directions. However, sediments were blocked by the tidal shear front near the coast, which narrowed the diffusion range of sediments significantly. Compared with artificial floods, the impact of rainstorm flood on estuarine salinity was relatively small, the plume diffusion range was relatively limited, and the sediment diffusion range was less different from that of artificial flood, which is in line with the sedimentation range of sediment entering the sea under the barrier of tidal shear front. The runoff of the flood event also caused a high degree of water stratification in the Yellow River Estuary. The buoyancy frequency of the surface water mass could reach more than 10−1 s−2, which was an order of magnitude difference from the buoyancy frequency after the flood. However, the buoyancy frequency of the middle and bottom water column change less during and after the flood, which is mixes well than the surface water column.
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Keywords:
- rainstorm flood /
- Yellow River Estuary /
- sediment dispersal /
- diluted water /
- stratification
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References
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XU Hehe, LIU Surui, CHEN Jianbin, WANG Houjie, BI Naishuang, YU Yongqing, WANG Yamei, WU Xiao. Variations of hydrological characteristics off the Yellow River Estuary induced by the “7·20” rainstorm flood in Henan Province[J]. Marine Geology Frontiers, 2025, 41(2): 78-91. doi: 10.16028/j.1009-2722.2024.025
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Figure 1.
Statistics of rainfall in the “7·20” rainstorm flood
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Figure 2.
Location of the study area and deployment of the sampling station in the Yellow River estuary
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Figure 3.
Comparison of turbidity and salinity inverted by remote sensing with measured data
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Figure 4.
River discharge and suspended sediment concentration at Huayuankou and Lijin stations from July 18 to August 3, 2021
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Figure 5.
Sea surface salinity distributions during the flood period derived from GOCI images
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Figure 6.
Sea surface turbidity distributions during the flood period derived from GOCI images
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Figure 7.
Variations in salinity and turbidity in the early, late, and after flood at section C
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Figure 8.
Variations of salinity and turbidity in the late and after flood at section B
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Figure 9.
Vertical profiles of density and buoyancy frequency in the early, late, and after flood at station C1, C2 and C3
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Figure 10.
Vertical profiles of density and buoyancy frequency in the late and after flood at station B1, B2 and B3