| Qingdao Institute of marine geology, China Geological Survey | Host |
| Citation: |
WANG Ti, CONG Shuai, CHEN Jianbin, WANG Hanrui, WEI Yisu, ZHU Pengyu, WANG Houjie, WU Xiao. Variations in sedimentation characteristics of the Yellow River Delta under the remote influence of Typhoon Doksuri[J]. Marine Geology & Quaternary Geology, 2024, 44(5): 50-57. doi: 10.16562/j.cnki.0256-1492.2024071601
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Variations in sedimentation characteristics of the Yellow River Delta under the remote influence of Typhoon Doksuri
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Abstract
To explore the influence of a non-directly passing typhoon on the sedimentary dynamic environment and characteristics of the Yellow River Delta, the impact of the peripheral wind field of Typhoon Doksuri in 2023 on the sedimentary environment of the deltaic area was studied through a combination of in-situ observations, unmanned aerial vehicle (UAV) remote sensing, field survey sampling, and laboratory analysis. Results indicate that: (1) The peripheral wind field of the typhoon caused a rapid change in wind pattern in the delta region, enhanced the estuarine dynamics, and triggered the resuspension of sediments. (2) Variations in marine dynamics resulted in different cross-sectional characteristics within the estuarine delta, which reduced the elevation in the nearshore segment and increased the tidal creeks landside. Due to coastal engineering, sedimentation was increased notably near Kendong 12 Block of the Shengli Oilfield in the study area after the typhoon. The abandoned Qingshuigou River channel experienced erosion seaward and sedimentation shoreward. (3) In addition to the elevation change, significant changes in sediment grain size occurred in different cross-sections of the delta. The changes in grain size were influenced by various factors such as tidal creek erosion, river sediment transport, estuarine erosion, and filling of abandoned river channels, showing spatial differences. The findings of the study demonstrate that typhoons do not directly pass through the delta can still affect the sedimentary evolution process in this region through their peripheral wind field, which should be taken into consideration seriously in future research on delta sedimentary evolution and disaster prevention and mitigation efforts.
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Keywords:
- Typhoon Doksuri /
- remote influence /
- sedimentary dynamics /
- delta evolution /
- Yellow River Delta
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References
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WANG Ti, CONG Shuai, CHEN Jianbin, WANG Hanrui, WEI Yisu, ZHU Pengyu, WANG Houjie, WU Xiao. Variations in sedimentation characteristics of the Yellow River Delta under the remote influence of Typhoon Doksuri[J]. Marine Geology & Quaternary Geology, 2024, 44(5): 50-57. doi: 10.16562/j.cnki.0256-1492.2024071601
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Figure 1.
The landing and evolution path of Typhoon Doksuri in July 2023, and the wind field characteristics on July 29 (a) , and the scope of the study area, as well as the distribution of survey sections and stations (b)
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Figure 2.
The wind field characteristics in the Yellow River Delta region on July 23, July 29, and August 4 (a-c, respectively) , and the regional-averaged wind vectors in the Yellow River Delta from July 21 to August 4 (d)
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Figure 3.
Buoy observation data at Station S1 in the Yellow River estuary from July 21 to August 4
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Figure 4.
Changes in elevation of sections A-G before and after the typhoon passage
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Figure 5.
On-site photos of different landscapes in the Yellow River Delta before the typhoon (a-d) and comparison images of the same location before and after the typhoon passage (e-f)
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Figure 6.
Characteristics of median grain size changes in sediments at each section before and after the typhoon