Effect of tides on river water behavior over the eastern shelf seas of China

Rivers carry large amounts of freshwater and terrestrial material into shelf seas, which is an important part of the global water and biogeochemical cycles. The earth system model or climate model is an important instrument for simulating and projecting the global water cycle and climate change, in...

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Bibliographic Details
Published in:Hydrology and earth system sciences 2022-10, Vol.26 (20), p.5207-5225
Main Authors: Lin, Lei, Liu, Hao, Huang, Xiaomeng, Fu, Qingjun, Guo, Xinyu
Format: Article
Language:English
Subjects:
Biogeochemical cycle
Biogeochemical cycles
Biogeochemistry
Bottom stress
Carbon cycle
Climate change
Climate models
Climatic changes
Coasts
Comparative analysis
Fluid mechanics
Freshwater
Hydrologic cycle
Hydrological cycle
Inland water environment
Modelling
Ocean circulation
Oceans
Parameterization
River discharge
River flow
River runoff
River water
Rivers
Runoff
Salinity
Sea currents
Seawater
Seawater salinity
Shelf currents
Shelf seas
Shelving
Simulation
Tidal effects
Tides
Transit time
Transport
Water
Water currents
Water cycle
Water transport
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Summary:Rivers carry large amounts of freshwater and terrestrial material into shelf seas, which is an important part of the global water and biogeochemical cycles. The earth system model or climate model is an important instrument for simulating and projecting the global water cycle and climate change, in which tides however are commonly removed. For a better understanding of the potential effect of the absence of tides in the simulation of the water cycle, this study compared the results of a regional model with and without considering tides, and evaluated the effect of tides on the behavior of three major rivers (i.e., the Yellow, Yalujiang, and Changjiang rivers) water in the eastern shelf seas of China from the perspectives of transport pathways, timescales, and water concentration. The results showed that the tides induced more dispersed transport for the water of the Yellow and Yalujiang rivers, but more concentrated transport for the Changjiang River water. The effect of tides on the transit areas of the Yellow, Yalujiang, and Changjiang rivers was 13 %, 40 %, and 21 %, respectively. The annual mean water age and transit time of the three rivers in the model with tides were several (∼ 2–10) times higher than those in the no-tide model, suggesting that tides dramatically slow the river water transport and export rate over the shelf. By slowing the river water export, tides induced a three-fold increase in river water concentration and a decrease in shelf seawater salinity by > 1. Moreover, the effect of tides on river behavior was stronger in relatively enclosed seas (i.e., the Bohai and Yellow seas) than in relatively open seas (i.e., the East China Sea). The change in the shelf currents induced by tides is the main cause of the difference in the river water behavior between the two model runs. Tides can increase bottom stress and thus weaken shelf currents and decrease the water transport timescales. The improvement in tidal parameterization in the no-tide model in the simulation of river water behavior was very limited. Given the important role of river runoff on the global water cycle and the effect of changes in river water behavior on ocean carbon cycling, it is important to include the tidal effect in earth system models to improve their projection accuracy.
ISSN:1607-7938
1027-5606
1607-7938
DOI:10.5194/hess-26-5207-2022