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Simplicity in Braiding Rivers

Simplicity in Braiding Rivers. Peter Ashmore University of Western Ontario S é minaire GESTRANS, Grenoble, Nov 21, 2012. Thanks to:. UWO students Roey Egozi, Tobi Gardner, Beth Hundey Many lab, field and data assistants BOKU: Helmut Habersack and students

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Simplicity in Braiding Rivers

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  1. Simplicity in Braiding Rivers Peter Ashmore University of Western Ontario Séminaire GESTRANS, Grenoble, Nov 21, 2012

  2. Thanks to: • UWO students Roey Egozi, Tobi Gardner, Beth Hundey • Many lab, field and data assistants • BOKU: Helmut Habersack and students • U. Trento visitors to Sunwapta 1999 and 2003 + Chris Paola • Walter Bertoldi – it’s all his fault  • Jim Chandler – Loughborough University • ….and John Shaw & Gary Parker • Funding provided mainly by: • Natural Science and Engineering Research Council of Canada (NSERC) • CFI-Canada Foundation for Innovation (flume construction costs)

  3. The ‘threshold’ separating braiding from other morphological types leads to idea that braided rivers are ‘different’ even though we recognise a continuum of channel patterns. • Visual appearance suggests complexity. • …… but a series of observations suggest that there is order and structure in braiding channel pattern, morphology and kinetics across a range of braiding rivers which lead to some core relationships describing and predicting braiding morphology and processes: • Cross-section dimensions and hydraulic geometry • Bars and planform scaling (unit morphology) • Constraints on braiding intensity • Bed load transport and morphology

  4. Hydraulic geometry (e.g. depth) of anabranches and confluences follow the same scaling Physical model Sunwapta R., Canada + Mosley (1981a) data Ohau R. NZ Ashmore & Gardner 2008

  5. Regime geometry of wetted cross-section Total wetted width Ashmore 2001 & in press Treatise on Geomorphology Mean depth

  6. 2. Bars and planform scaling Ashmore 2009 (and 1982, ’91)

  7. Braiding is series of confluences and bifurcations – mean spacing (along channel) scales with total discharge Ashmore, 2001

  8. Length of Confluence –Bifurcation units Hundey & Ashmore 2009

  9. Results from flume show linear relationship between length and width (two possible regression results). Hundey and Ashmore 2009

  10. Comparison with field data suggest scaling very similar to pool-pool spacing in meandering channels or alternate bars and very similar to “incipient braids” And bigger (larger Q) rivers have longer average length But if channels are complex and have range of sizes, how is length scaled with total river discharge? – relates to braiding intensity and minimum size and number of active channels

  11. 3. Regime braiding intensity “..this consecutive branching process,…, perpetuates itself until the equilibrium or regime state is reached.” Yalin and da Silva 2001 but what is this state and how does it develop?

  12. Braiding intensity varies with stream power Data from Ashmore flume experiments (1985) & Mosley (1981b) Ashmore 2009

  13. TBI, ABI and ratio are all ‘regime’ states TBI ABI Egozi & Ashmore 2009

  14. Channel pattern is developed over time by progressive migration of only a few active channels (usually 2 or less) Morphology and dynamics controlled by one or two major active channels and related bifurcation / confluence / switching Egozi and Ashmore 2009

  15. Gardner PhD thesis 2009

  16. Flow

  17. ABI & braid ratio vary – predictable average values that vary with stream power relative to grain size Bertoldi et al. 2009b Egozi & Ashmore 2009

  18. 4. Sediment transport and active width Bertoldi et al., 2009a

  19. Flux increase seems to depend more on active width than on bed stress changes – and there seems to be a predictable function for mean active width Bertoldi et al., 2008

  20. Reduced to systematic relationship with dimensionless power Bertoldi et al. 2009a

  21. Field observations (repeat daily cross-section surveys during daily melt hydrograph sequence), Sunwapta River, Alberta – takes us back to transient shifting of activity Ashmore et al. 2011

  22. Variation with discharge in a reach Variation of mean active width at ‘channel-forming’ flows ? Ashmore et al. 2011

  23. Which brings us back to regime for ABI/TBI and possible approximations relating active width (and bedload flux) to observable (TBI) and inference to ABI? Bertoldi et al. 2009b

  24. …but it’s still complex!

  25. Braiding rivers have average ‘regime’ morphology for: • individual channels, local features and total channel cross-section dimensions • Scale of unit features such as bars and confluence-diffluence • Complexity of braiding network (braiding intensity) – both total and ‘active’ • Well-defined relationship for total sediment (bed load) flux • Variation in active width ‘at a station’ and for overall variation in dimensionless stream power - which also relates to bed load transport • Braiding rivers regime morphology and there is a continuum of morpho-dynamic characteristics determined mainly by sediment mobility and river size (total discharge) – and they have internal regime relations between channel size, braid length and complexity, active width and bedload flux. • ….

  26. References • Ashmore, P.E., 1982. Laboratory modelling of gravel braided river morphology, Earth Surface Processes and Landforms, 7, 201-225 • Ashmore, P.E., 1985. Process and form in gravel braided streams: laboratory modelling and field observations. PhD thesis, University of Alberta. • Ashmore, P.E., 1991. How do gravel-bed streams braid? Canadian Journal of Earth Sciences, 28, 326-341 • Ashmore, P., 2001. Braiding phenomena: statics and kinetics. In, M.P. Mosley (Editor), Gravel-Bed Rivers V, New Zealand Hydrological Society, Wellington, 95-114. • Ashmore, P. 2009. The intensity and characteristic length of braided channel patterns. Canadian Journal of Civil Engineering, 36, 1656-1666.(Invited paper for a special issue in honour of Prof. S. Yalin) • Ashmore, P. In press. Morphology and dynamics of braided rivers. In: Schroder, J. Jr., E. Wohl (Eds.) Treatise on Geomorphology. Academic Press, San Diego. • Egozi, R., and P. Ashmore 2009. Experimental analysis of braided channel pattern response to increased discharge, J. Geophys. Res., 114, F02012, doi:10.1029/2008JF001099. • Ashmore, P. and Gardner, J.T. 2008. Unconfined confluences in braided rivers. Rice, S., Roy, A. Rhoads, B. (editors) River Confluences, Tributaries and the Fluvial Network. Wiley, Chichester, 119-143 • Ashmore, P. , Bertoldi, W. and Gardner, J.T. 2011. Active width of gravel-bed braided rivers. Earth Surface Processes and Landforms. 36, 1510-1521. DOI: 10.1001:esp2182 • Bertoldi, W., Ashmore, P. and Tubino, M. ,2009a . A method for estimating the mean bed load flux in braided rivers. Geomorphology 109, 330-340 • Bertoldi, W., Zanoni, L., Tubino, M., 2009b. Planform dynamics of braided streams. Earth Surface Processes and Landforms, 34, 547-557. • Hundey, E. and Ashmore, P. 2009. Length scale of braided river morphology. Water Resources Research, 45, W08409, doi:10.1029/2008WR007521. • Mosley, P.M., 1981. Semi-determinate hydraulic geometry of river channels, South Island, New Zealand. Earth Surface Processes and Landforms, 6, 127-137. • Mosley, M.P., 1981. Scour depths in branch channel confluences, Ohau River. Report no. WS 395, Ministry of Works and Development, Christchurch, New Zealand.

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