Flood-ebb asymmetry in current velocity and suspended sediment transport in the Changjiang Estuary

LI Zhanhai; WANG Yaping; CHENG Peng; ZHANG Guoan; LI Jiufa

doi:10.1007/s13131-016-0923-9

长江口涨潮与落潮流速和悬沙输运不对称性研究

doi: 10.1007/s13131-016-0923-9

1.
河口海岸学国家重点实验室, 华东师范大学, 上海 200062, 中国
2.
地理与海洋科学学院, 南京大学, 南京 210093, 中国
3.
海洋与地球学院, 厦门大学, 厦门 361005, 中国

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出版历程
- 收稿日期: 2015-08-27
- 修回日期: 2015-10-23

Flood-ebb asymmetry in current velocity and suspended sediment transport in the Changjiang Estuary

1.
State Key Laboratory of Estuarine and Coastal Research, East China Normal University, Shanghai 200062, China
2.
School of Geographic and Oceanographic Sciences, Nanjing University, Nanjing 210093, China
3.
College of Ocean and Earth Sciences, Xiamen University, Xiamen 361005, China

摘要

摘要: 2011年洪季在长江口南支开展了小潮至大潮连续的流速和悬沙浓度现场观测，基于该资料对流速和悬沙输沙的涨落潮不对称性进行了研究。结果表明在强径流和潮汐变形的共同影响下，南支的落潮流速和历时显著强于涨潮，流速的涨落潮不对称现象十分显著。悬沙浓度和悬沙粒径亦有明显的涨落潮变化，落潮显著大于涨潮，并且由小潮向大潮不断增加。流速和悬沙浓度的涨落潮不对称性导致南支的落潮输沙强度显著大于涨潮，各潮周期的净输沙方向向海。通量机制分解法的研究结果揭示，南支向海输沙主要受径流和潮汐捕集控制，向陆输沙主要受斯托克斯漂流和剪切效应控制。再悬浮作用在中大潮期间十分明显，流速与底层悬沙浓度和悬沙粒径的关系揭示涨潮与落潮期间的底质临界再悬浮流速分别约为40 cm/s和80 cm/s。临界再悬浮流速的涨落潮变化跟底质的空间分布差异密切相关，它对悬沙浓度的时间变化和悬沙输运过程会产生重要影响。在底质空间分布复杂的河口里，临界再悬浮流速存在涨落潮变化应该是一种普遍现象。
- 涨落潮不对称 /
- 悬沙浓度 /
- 再悬浮 /
- 径流 /
- 通量 /
- 长江口
Abstract: Time series measurements were conducted on suspended sediment and current velocity from neap tide to spring tide in the South Branch of the upper Changjiang Estuary in the summer of 2011. Strong flood-ebb asymmetry in the current velocity was observed in the South Branch as a result of high river runoff and tide deformation, in which the magnitude and duration of ebb currents were significantly greater than those of flood currents. The suspended sediment concentration (SSC) and suspended median grain size also exhibited remarkable flood-ebb variation; these variables were considerably larger during the ebb than during the flood and increased from neap to spring tide. Affected by the strong asymmetry in the current velocity and SSC between the flood and ebb, suspended sediment flux during the ebb was notably larger than during the flood, and a seaward tidal net flux was observed in each tidal cycle. The balance of sediment flux illustrates that the seaward sediment transport was dominated by river flow and tidal trapping and the landward sediment transport was dominated by the Stokes drift and the shear effect. Notable resuspension occurred during the spring and moderate tides. The critical velocity for the resuspension of bed sediments was estimated based on the correlation between current velocity with SSC and suspended median grain size. The results show that the critical velocity was approximately 40 cm/s during the flood phases and approximately 80 cm/s during the ebb phases because the surficial flood bed sediments located in the lower reach are much finer than the surficial ebb bed sediments located in the upper reach. The flood-ebb variation in the critical erosion velocity has significant effect on the intratidal variation of SSC and sediment transport process, and it is a common phenomenon in many estuaries of the world due to the complicated spatial distribution of bed sediments.
- flood-ebb asymmetry /
- suspended sediment concentration /
- resuspension /
- river runoff /
- flux /
- the upper Changjiang Estuary

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参考文献(46)

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长江口涨潮与落潮流速和悬沙输运不对称性研究

doi: 10.1007/s13131-016-0923-9

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出版历程

Flood-ebb asymmetry in current velocity and suspended sediment transport in the Changjiang Estuary

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