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Causes of rapid mixing at a junction of two large rivers : Río Paraná and Río Paraguay, Argentina.

By S. N. Lane, D. R. Parsons, J. L. Best, O. Orfeo, R. Kostaschuk and R. J. Hardy


Airborne and satellite observations show that when large rivers join they can take hundreds of kilometers to mix completely but, on occasion, may mix very rapidly. Application of established semitheoretical analyses shows that long mixing lengths should be expected. The first measurements of mixing processes at a large river junction (Río Paraná and Río Paraguay, Argentina, combined width ∼2.8 km) are presented at two occasions: first when they mix in >400 km, and second when mixing is complete in only 8 km downstream of the junction. For the case of slower mixing, at‐a‐point surveys showed that mixing driven by turbulent shear associated with a near‐vertical shear layer was restricted to close to the junction (to 0.272 multiples of the postconfluence width downstream). Transect surveys showed penetration of more turbid water from the Río Paraguay underneath the Río Paraná, but this was insufficient to promote more rapid mixing. There was no clear channel‐scale circulation present and slow mixing was compounded by reverse topographic forcing on the mainstream Río Paraná side of the river. This kept more turbid water on the Río Paraguay side of the river, close to the bed. In the case of rapid mixing, we found clear channel‐scale circulation. The momentum ratio between the combining flows reinforced the effects of the discordance in bed height between the tributaries at the confluence and allowed penetration of more turbid Río Paraguay water further across the channel width deeper within the flow. The importance of the interaction between momentum ratio and bed morphology at channel junctions makes mixing rates at the confluence dependent upon basin‐scale hydrological response, which is more likely to differ between large confluent rivers than small rivers, as a result of the different climatic/topographic zones that they may capture

Topics: Confluence, Junction, Mixing, Advection, Turbidity, Large rivers.
Publisher: American Geophysical Union
Year: 2008
DOI identifier: 10.1029/2006JF000745
OAI identifier: oai:dro.dur.ac.uk.OAI2:7274

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  12. (1984). On Playfair’s law of accordant junctions,
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  17. (1970). Lateral mixing of the Laird and Mackenzie rivers downstream from their confluence, doi
  18. (1976). Isotopic hydrology of the Amazonia: 2. Relative discharge of the Negro and Solimo˜es rivers through 18 concentrations, doi
  19. (1996). The origin and downstream development of coherent flow structures at channel junctions, in Coherent Flow Structures in Open Channels, doi
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