Acoustic Doppler current profiler surveys along the Yangtze River

An acoustic Doppler current profiler is used to characterize the river velocity against the morphology of the Yangtze River from Chonqing to the sea. High flow velocities occur in the Three Gorges section and lower velocities in the middle and lower reaches of the river. This is largely due to the change in river pattern from a high gradient deeply-cut valley to a flat fluvial plain. Flow velocities fluctuate in the middle Yangtze due to the presence of meander bends of different length. There are numerous smaller velocity fluctuations in the lower Yangtze channel that reflect multichannel pattern with numerous sand bars and a river morphology affected by bedrock outcrops. Water depths of 40-100 m occur in the Three Gorges valley but decrease to 15-40 m in the middle and lower Yangtze. At the Gezhou Reservoir, 30 km downstream of the Three Gorges damsite velocity drops to low (< 1.0 m s -1 ) 20 km reach. A second low velocity (<0.5 m s -1 ) zone, about 20 km in length, is located in the lower Yangtze near the coast probably due to the tidal influence. The results from this research will serve as a datum for evaluating changes to the river once the Three Gorges dam is completed in 2009.

[1]  Roberto Baratti,et al.  River flow forecast for reservoir management through neural networks , 2003, Neurocomputing.

[2]  B. Makaske Anastomosing rivers: a review of their classification, origin and sedimentary products , 2001 .

[3]  S. L. Yang,et al.  Temporal variation in the sediment load of the Yangtze river and the influences of human activities , 2002 .

[4]  Yan Zhao,et al.  Interpretation of the environmental change of Dongting Lake, middle reach of Yangtze River, China, by 210Pb measurement and satellite image analysis , 2001 .

[5]  T. Jiang,et al.  Channel morphology and its impact on flood passage, the Tianjiazhen reach of the middle Yangtze River , 2007 .

[6]  O. Borisova,et al.  Channel morphology and river flow in the northern Russian Plain in the Late Glacial and Holocene , 2000 .

[7]  Zhongyuan Chen,et al.  Sediment rating parameters and their implications: Yangtze River, China , 2007 .

[8]  N. Reynard,et al.  The effects of climate change due to global warming on river flows in Great Britain , 1996 .

[9]  Estimating mean flow velocity in channel and floodplain areas and its use for explaining the pattern of overbank deposition and floodplain retention , 1999 .

[10]  Chang’an Li,et al.  On the river–lake relationship of the middle Yangtze reaches , 2007 .

[11]  K. Oberg,et al.  Measuring river velocity and discharge with acoustic Doppler profilers , 2002 .

[12]  Shiyou Xie,et al.  Geomorphic evolution of the Yangtze Gorges and the time of their formation , 2001 .

[13]  J. Best,et al.  Measuring flow velocity and sediment transport with an acoustic Doppler current profiler , 2005 .

[14]  V. Kale,et al.  Effectiveness of monsoon floods on the Tapi River, India: role of channel geometry and hydrologic regime , 2004 .

[15]  Andrew J. Miller,et al.  Varieties of Fluvial Form , 1999 .

[16]  G. Grant,et al.  A Peculiar River: Geology, Geomorphology, and Hydrology of the Deschutes River, Oregon , 2003 .

[17]  Nicholas Pinter,et al.  Hydrodynamic and morphodynamic response to river engineering documented by fixed-discharge analysis, Lower Missouri River, USA , 2005 .

[18]  J. Guyot,et al.  The use of Doppler technology for suspended sediment discharge determination in the River Amazon / L’utilisation des techniques Doppler pour la détermination du transport solide de l’Amazone , 2004 .

[19]  Richard D. Hey,et al.  Applied fluvial geomorphology for river engineering and management. , 1997 .

[20]  M. Dima,et al.  Decadal variability of the Danube river flow in the lower basin and its relation with the North Atlantic Oscillation , 2002 .