Braided river

A braided river (also called braided channel or braided stream) consists of a network of river channels separated by small, often temporary, islands called braid bars or, in British English usage, aits or eyots.

Braided streams tend to occur in rivers with high sediment loads or coarse grain sizes, and in rivers with steeper slopes than typical rivers with straight or meandering channel patterns. They are also associated with rivers with rapid and frequent variation in the amount of water they carry, i.e., with "flashy" rivers, and with rivers with weak banks.

Braided channels are found in a variety of environments all over the world, including gravelly mountain streams, sand bed rivers, on alluvial fans, on river deltas, and across depositional plains.^[1]

Description

A braided river consists of a network of multiple shallow channels that diverge and rejoin around ephemeral braid bars. This gives the river a fancied resemblance to the interwoven strands of a braid.^[2]^[3] The braid bars, also known as channel bars,^[4] branch islands,^[5] or accreting islands, are usually unstable and may be completely covered at times of high water.^[3] The channels and braid bars are usually highly mobile, with the river layout often changing significantly during flood events.^[6] When the islets separating channels are stabilized by vegetation, so that they are more permanent features, they are sometimes called aits or eyots.^[7]

A braided river differs from a meandering river, which has a single sinuous channel. It is also distinct from an anastomosing river, which consist of multiple interweaving semi-permanent channels which are separated by floodplain rather than channel bars; these channels may themselves be braided.^[3]

Formation

The physical processes that determine whether a river will be braided or meandering are not fully understood.^[8]^[9] However, there is wide agreement that a river becomes braided when it carries an abundant supply of sediments.^[2]^[8]^[10]

Experiments with flumes suggest that a river becomes braided when a threshold level of sediment load or slope is reached. On timescales long enough for the river to evolve, a sustained increase in sediment load will increase the bed slope of the river, so that a variation of slope is equivalent to a variation in sediment load, provided the amount of water carried by the river is unchanged. A threshold slope was experimentally determined to be 0.016 (ft/ft) for a 0.15 cu ft/s (0.0042 m³/s) stream with poorly sorted coarse sand. Any slope over this threshold created a braided stream, while any slope under the threshold created a meandering stream or – for very low slopes – a straight channel. Also important to channel development is the proportion of suspended load sediment to bed load. An increase in suspended sediment allowed for the deposition of fine erosion-resistant material on the inside of a curve, which accentuated the curve and in some instances, caused a river to shift from a braided to a meandering profile.^[11]

These experimental results were expressed in formulas relating the critical slope for braiding to the discharge and grain size. The higher the discharge, the lower the critical slope, while larger grain size yields a higher critical slope. However, these give only an incomplete picture,^[8] and numerical simulations have become increasingly important for understanding braided rivers.^[12]^[9]

Aggradation (net deposition of sediments) favors braided rivers, but is not essential. For example, the Rakaia and Waitaki Rivers of New Zealand are not aggrading, due to retreating shorelines, but are nonetheless braided rivers. Variable discharge has also been identified as important in braided rivers,^[13] but this may be primarily due to the tendency for frequent floods to reduce bank vegetation and destabilize the banks, rather than because variable discharge is an essential part of braided river formation.^[14]

Numerical models suggest that bedload transport (movement of sediment particles by rolling or bouncing along the river bottom) is essential to formation of braided rivers, with net erosion of sediments at channel divergences and net deposition at convergences. Braiding is reliably reproduced in simulations whenever there is little lateral constraint on flow and there is significant bedload transport. Braiding is not observed in simulations of the extreme cases of pure scour (no deposition taking place), which produces a dendritic system, or of cohesive sediments with no bedload transport. Meanders fully develop only when the river banks are sufficiently stabilized to limit lateral flow.^[9] An increase in suspended sediment relative to bedload allows the deposition of fine erosion-resistant material on the inside of a curve, which accentuated the curve and in some instances, causes a river to shift from a braided to a meandering profile.^[11] A stream with cohesive banks that are resistant to erosion will form narrow, deep, meandering channels, whereas a stream with highly erodible banks will form wide, shallow channels, preventing the helical flow of the water necessary for meandering and resulting in the formation of braided channels.^[15]

Occurrences

Brahmaputra River seen from the Space Shuttle

Braided rivers occur in many environments, but are most common in wide valleys associated with mountainous regions or their piedmonts^[14] or in areas of coarse-grained sediments and limited growth of vegetation near the river banks.^[16] They are also found on fluvial (stream-dominated) alluvial fans.^[17] Extensive braided river systems are found in Alaska, Canada, New Zealand's South Island, and the Himalayas, which all contain young, rapidly eroding mountains.

The enormous Brahmaputra river in Northeastern India is a classic example of a braided river.^[18]
A notable example of a large braided stream in the contiguous United States is the Platte River in central and western Nebraska.^[19] Platte-type braided rivers are characterized by abundant linguoid (tonguelike) bar and dune deposits.^[20]
The Scott River of southern Alaska is the type for braided glacial outwash rivers characterized by longitudinal gravel bars and by sand lenses deposited in scours from times of high water.^[20]
The Donjek River of the Yukon Basin is the type for braided rivers showing repeated cycles of deposition, with finer sediments towards the top of each cycle.^[20]
The Bijou Creek of Colorado is the type for braided rivers characterized by laminated sand deposits emplaced during floods.^[20]
A portion of the lower Yellow River takes a braided form.^[21]
The Sewanee Conglomerate, a Pennsylvanian coarse sandstone and conglomerate unit^[22] present on the Cumberland Plateau near the University of the South, may have been deposited by an ancient braided and meandering river that once existed in the eastern United States.^[23] Others have interpreted the depositional environment for this unit as a tidal delta.^[24]

The Tagliamento of Italy is an example of a gravel bed braided river.^[26]
The Piave, also in Italy, is an example of a river that is transitioning from braided to meandering due to human interventions.^[27]
The Waimakariri River of New Zealand is an example of a braided river with an extensive floodplain.^[28]
The Hawkesbury Sandstone of Sydney is commonly interpreted as having been deposited by a large braided river system that existed during the Triassic period in Australia.^[29]

Waimakariri River with the Southern Alps in the background, Canterbury, New Zealand
Rakaia River, South Island, New Zealand
Tanana River, Fairbanks, Alaska, United States
Toklat River, Denali National Park and Preserve, Alaska, United States
Medano Creek, Great Sand Dunes National Park and Preserve, Colorado, United States

References

^ Bristow, C. S.; Best, J. L. (1 January 1993). "Braided rivers: perspectives and problems". Geological Society, London, Special Publications. 75 (1): 1–11. Bibcode:1993GSLSP..75....1B. doi:10.1144/GSL.SP.1993.075.01.01. S2CID 129232374.
^ ^a ^b Jackson, Julia A., ed. (1997). "braided stream". Glossary of geology (Fourth ed.). Alexandria, Virginia: American Geological Institute. ISBN 0922152349.
^ ^a ^b ^c Leeder, M. R. (2011). Sedimentology and sedimentary basins : from turbulence to tectonics (2nd ed.). Chichester, West Sussex, UK: Wiley-Blackwell. pp. 247–252. ISBN 9781405177832.
^ Jackson 1997, "channel bar".
^ Jackson 1997, "branch island".
^ Hickin, E; Sichingabula, H (1988). "The geomorphic impact of the catastrophic October 1984 flood on the planform of the Squamish River, southwestern British Columbia". Canadian Journal of Earth Sciences. 25 (7): 1078–1087. Bibcode:1988CaJES..25.1078H. doi:10.1139/e88-105.
^ Allaby, Michael (2013). A dictionary of geology and earth sciences (Fourth ed.). Oxford: Oxford University Press. ISBN 9780199653065.
^ ^a ^b ^c Leeder 2011, p. 248.
^ ^a ^b ^c Murray, A. Brad; Paola, Chris (September 1994). "A cellular model of braided rivers". Nature. 371 (6492): 54–57. Bibcode:1994Natur.371...54M. doi:10.1038/371054a0. S2CID 4276051.
^ Gray, D.; Harding, J.S. (2007). "Braided river ecology: A literature review of physical habitats and aquatic invertebrate communities" (PDF). Science for Conservation 279. Wellington: New Zealand Department of Conservation. ISBN 978-0-478-14341-6. Retrieved 19 July 2025.
^ ^a ^b Schumm, S; Kahn, H (1972). "Experimental Study of Channel Patterns". Bulletin of the Geological Society of America. 83 (6): 1755–1770. doi:10.1130/0016-7606(1972)83[1755:esocp]2.0.co;2.
^ Williams, Richard D.; Brasington, James; Hicks, D. Murray (March 2016). "Numerical Modelling of Braided River Morphodynamics: Review and Future Challenges: Modelling Braided River Morphodynamics" (PDF). Geography Compass. 10 (3): 102–127. doi:10.1111/gec3.12260.
^ Leopold, L.B.; Wolman, M.G. (1957). "River channel patterns: Braiding, meandering, and straight". U.S. Geological Survey Professional Papers. Professional Paper. 282-B: 39–85. Bibcode:1957usgs.rept....7L. doi:10.3133/pp282B.
^ ^a ^b Williams, Brasington & Hicks 2016, p. 104.
^ Easterbrook, Don J. (1999). Surface processes and landforms (2nd ed.). Upper Saddle River, New Jersey: Prentice Hall. ISBN 978-0138609580.
^ Ashmore, P. (2013). "9.17 Morphology and Dynamics of Braided Rivers". Treatise on Geomorphology: 289–312. doi:10.1016/B978-0-12-374739-6.00242-6. ISBN 9780080885223.
^ Boggs, Sam Jr. (2006). Principles of sedimentology and stratigraphy (4th ed.). Upper Saddle River, New Jersey: Pearson Prentice Hall. p. 248. ISBN 0131547283.
^ Catling, David (1992). Rice in deep water. International Rice Research Institute. p. 177. ISBN 978-971-22-0005-2. Retrieved 23 April 2011.
^ Blodgett, R.H.; Stanley, K.O. (1980). "Stratification, Bedforms, and Discharge Relations of the Platte Braided River System, Nebraska". SEPM Journal of Sedimentary Research. 50 (1). doi:10.1306/212F7987-2B24-11D7-8648000102C1865D.
^ ^a ^b ^c ^d Miall, Andrew D. (May 1977). "A review of the braided-river depositional environment". Earth-Science Reviews. 13 (1): 1–62. Bibcode:1977ESRv...13....1M. doi:10.1016/0012-8252(77)90055-1.
^ Chien, N. (1961). "The braided stream of the lower Yellow River". Scientia Sinica. 10: 734–754.
^ Fraley, Thear Kirk (13–16 March 2010). Depositional Environment of Lower Pennsylvanian Sewanee Conglomerate, Lookout Mountain, Georgia. Geological Society of America Northeastern Section (45th Annual) and Southeastern Section (59th Annual) Joint Meeting.
^ Churnet, Habte Giorgis; Bergenback, Richard E. (1986). Depositional Systems of Pennsylvanian Rocks in the Cumberland Plateau of Southern Tennessee. Georgia Geological Society.
^ Ferm, J. C.; Miliei, R. C.; Eason, J.E. (1972). "Carboniferous depositional environments in the Cumberland Plateau of Southern Tennessee and Northern Alabama". Tennessee Div. Geology Rept. Inv. (33).
^ "Google Maps".
^ Bertoldi, W.; Zanoni, L.; Tubino, M. (January 2010). "Assessment of morphological changes induced by flow and flood pulses in a gravel bed braided river: The Tagliamento River (Italy)". Geomorphology. 114 (3): 348–360. Bibcode:2010Geomo.114..348B. doi:10.1016/j.geomorph.2009.07.017.
^ Surian, Nicola (8 November 1999). "Channel changes due to river regulation: the case of the Piave River, Italy". Earth Surface Processes and Landforms. 24 (12): 1135–1151. Bibcode:1999ESPL...24.1135S. doi:10.1002/(SICI)1096-9837(199911)24:12<1135::AID-ESP40>3.0.CO;2-F.
^ Reinfelds, Ivars; Nanson, Gerald (December 1993). "Formation of braided river floodplains, Waimakariri River, New Zealand". Sedimentology. 40 (6): 1113–1127. Bibcode:1993Sedim..40.1113R. doi:10.1111/j.1365-3091.1993.tb01382.x.
^ P. J. Conaghan, J. G. Jones (1 January 1975). "The hawkesbury sandstone and the brahmaputra: A depositional model for continental sheet sandstones". Macquarie University. Retrieved 15 December 2025.

External links

Media related to Braided rivers at Wikimedia Commons

[BristowBest-1] Bristow, C. S.; Best, J. L. (1 January 1993). "Braided rivers: perspectives and problems". Geological Society, London, Special Publications. 75 (1): 1–11. Bibcode:1993GSLSP..75....1B. doi:10.1144/GSL.SP.1993.075.01.01. S2CID 129232374.

[Jackson1997-2] Jackson, Julia A., ed. (1997). "braided stream". Glossary of geology (Fourth ed.). Alexandria, Virginia: American Geological Institute. ISBN 0922152349.

[Leeder2011-3] Leeder, M. R. (2011). Sedimentology and sedimentary basins : from turbulence to tectonics (2nd ed.). Chichester, West Sussex, UK: Wiley-Blackwell. pp. 247–252. ISBN 9781405177832.

[FOOTNOTEJackson1997"channel_bar"-4] Jackson 1997, "channel bar".

[FOOTNOTEJackson1997"branch_island"-5] Jackson 1997, "branch island".

[6] Hickin, E; Sichingabula, H (1988). "The geomorphic impact of the catastrophic October 1984 flood on the planform of the Squamish River, southwestern British Columbia". Canadian Journal of Earth Sciences. 25 (7): 1078–1087. Bibcode:1988CaJES..25.1078H. doi:10.1139/e88-105.

[7] Allaby, Michael (2013). A dictionary of geology and earth sciences (Fourth ed.). Oxford: Oxford University Press. ISBN 9780199653065.

[FOOTNOTELeeder2011248-8] Leeder 2011, p. 248.

[MurrayPaola1994-9] Murray, A. Brad; Paola, Chris (September 1994). "A cellular model of braided rivers". Nature. 371 (6492): 54–57. Bibcode:1994Natur.371...54M. doi:10.1038/371054a0. S2CID 4276051.

[Gray-10] Gray, D.; Harding, J.S. (2007). "Braided river ecology: A literature review of physical habitats and aquatic invertebrate communities" (PDF). Science for Conservation 279. Wellington: New Zealand Department of Conservation. ISBN 978-0-478-14341-6. Retrieved 19 July 2025.

[Schumm-11] Schumm, S; Kahn, H (1972). "Experimental Study of Channel Patterns". Bulletin of the Geological Society of America. 83 (6): 1755–1770. doi:10.1130/0016-7606(1972)83[1755:esocp]2.0.co;2.

[12] Williams, Richard D.; Brasington, James; Hicks, D. Murray (March 2016). "Numerical Modelling of Braided River Morphodynamics: Review and Future Challenges: Modelling Braided River Morphodynamics" (PDF). Geography Compass. 10 (3): 102–127. doi:10.1111/gec3.12260.

[Leopold-13] Leopold, L.B.; Wolman, M.G. (1957). "River channel patterns: Braiding, meandering, and straight". U.S. Geological Survey Professional Papers. Professional Paper. 282-B: 39–85. Bibcode:1957usgs.rept....7L. doi:10.3133/pp282B.

[FOOTNOTEWilliamsBrasingtonHicks2016104-14] Williams, Brasington & Hicks 2016, p. 104.

[Easterbrook,_Don_J._1999-15] Easterbrook, Don J. (1999). Surface processes and landforms (2nd ed.). Upper Saddle River, New Jersey: Prentice Hall. ISBN 978-0138609580.

[Ashmore2013-16] Ashmore, P. (2013). "9.17 Morphology and Dynamics of Braided Rivers". Treatise on Geomorphology: 289–312. doi:10.1016/B978-0-12-374739-6.00242-6. ISBN 9780080885223.

[17] Boggs, Sam Jr. (2006). Principles of sedimentology and stratigraphy (4th ed.). Upper Saddle River, New Jersey: Pearson Prentice Hall. p. 248. ISBN 0131547283.

[Catling1992-18] Catling, David (1992). Rice in deep water. International Rice Research Institute. p. 177. ISBN 978-971-22-0005-2. Retrieved 23 April 2011.

[19] Blodgett, R.H.; Stanley, K.O. (1980). "Stratification, Bedforms, and Discharge Relations of the Platte Braided River System, Nebraska". SEPM Journal of Sedimentary Research. 50 (1). doi:10.1306/212F7987-2B24-11D7-8648000102C1865D.

[Miall1977-20] Miall, Andrew D. (May 1977). "A review of the braided-river depositional environment". Earth-Science Reviews. 13 (1): 1–62. Bibcode:1977ESRv...13....1M. doi:10.1016/0012-8252(77)90055-1.

[21] Chien, N. (1961). "The braided stream of the lower Yellow River". Scientia Sinica. 10: 734–754.

[22] Fraley, Thear Kirk (13–16 March 2010). Depositional Environment of Lower Pennsylvanian Sewanee Conglomerate, Lookout Mountain, Georgia. Geological Society of America Northeastern Section (45th Annual) and Southeastern Section (59th Annual) Joint Meeting.

[23] Churnet, Habte Giorgis; Bergenback, Richard E. (1986). Depositional Systems of Pennsylvanian Rocks in the Cumberland Plateau of Southern Tennessee. Georgia Geological Society.

[24] Ferm, J. C.; Miliei, R. C.; Eason, J.E. (1972). "Carboniferous depositional environments in the Cumberland Plateau of Southern Tennessee and Northern Alabama". Tennessee Div. Geology Rept. Inv. (33).

[25] "Google Maps".

[26] Bertoldi, W.; Zanoni, L.; Tubino, M. (January 2010). "Assessment of morphological changes induced by flow and flood pulses in a gravel bed braided river: The Tagliamento River (Italy)". Geomorphology. 114 (3): 348–360. Bibcode:2010Geomo.114..348B. doi:10.1016/j.geomorph.2009.07.017.

[27] Surian, Nicola (8 November 1999). "Channel changes due to river regulation: the case of the Piave River, Italy". Earth Surface Processes and Landforms. 24 (12): 1135–1151. Bibcode:1999ESPL...24.1135S. doi:10.1002/(SICI)1096-9837(199911)24:12<1135::AID-ESP40>3.0.CO;2-F.

[28] Reinfelds, Ivars; Nanson, Gerald (December 1993). "Formation of braided river floodplains, Waimakariri River, New Zealand". Sedimentology. 40 (6): 1113–1127. Bibcode:1993Sedim..40.1113R. doi:10.1111/j.1365-3091.1993.tb01382.x.

[29] P. J. Conaghan, J. G. Jones (1 January 1975). "The hawkesbury sandstone and the brahmaputra: A depositional model for continental sheet sandstones". Macquarie University. Retrieved 15 December 2025.

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v t e River morphology
Large-scale features	Alluvial plain Drainage basin Drainage system (geomorphology) Estuary Strahler number (stream order) River valley River delta River sinuosity
Alluvial rivers	Anabranch Avulsion (river) Bar (river morphology) Braided river Channel pattern Cut bank Floodplain Meander Meander cutoff Mouth bar Oxbow lake Point bar Riffle Rapids Riparian zone River bifurcation River channel migration River mouth Slip-off slope Stream pool Thalweg
Bedrock river	Canyon Knickpoint Plunge pool
Bedforms	Ait Antidune Dune Current ripple
Regional processes	Aggradation Base level Degradation (geology) Erosion and tectonics River rejuvenation
Mechanics	Deposition (geology) Water erosion Exner equation Hack's law Helicoidal flow Playfair's law Sediment transport List of rivers that have reversed direction
Category

v t e Rivers, streams and springs
Rivers (lists)	Alluvial river Braided river Blackwater river Channel Channel pattern Channel types Confluence Distributary Drainage basin Mountain river Subterranean river River bifurcation River ecosystem River source Tributary
Streams	Arroyo Beck Bourne Burn Chalk stream Coulee Current Stream bed Stream channel Streamflow Stream gradient Stream pool Perennial stream Winterbourne
Springs (list)	Estavelle/Inversac Geyser Holy well Hot spring list list in the US Karst spring list Mineral spring Ponor Rhythmic spring Spring horizon
Sedimentary processes and erosion	Abrasion Anabranch Aggradation Armor Bed load Bed material load Granular flow Debris flow Deposition Dissolved load Downcutting Erosion Headward erosion Knickpoint Palaeochannel Progradation Retrogradation Saltation Secondary flow Sediment transport Suspended load Wash load Water gap
Fluvial landforms	Ait Alluvial fan Antecedent drainage stream Avulsion Bank Bar Bayou Billabong Canyon Chine Cut bank Estuary Floating island Fluvial terrace Gill Gulch Gully Glen Meander scar Mouth bar Oxbow lake Riffle-pool sequence Point bar Ravine Rill River island Rock-cut basin Sedimentary basin Sedimentary structures Strath Thalweg River valley Wadi
Fluvial flow	Helicoidal flow International scale of river difficulty Log jam Meander Plunge pool Rapids Riffle Shoal Stream capture Waterfall list of waterfalls Whitewater
Surface runoff	Agricultural wastewater First flush Urban runoff
Floods and stormwater	100-year flood Crevasse splay Flash flood Flood Urban flooding Non-water flood Flood barrier Flood control Flood forecasting Flood-meadow Floodplain Flood pulse concept Flooded grasslands and savannas Inundation Storm Water Management Model Return period
Point source pollution	Effluent Industrial wastewater Sewage
River measurement and modelling	Baer's law Baseflow Bradshaw model Discharge (hydrology) Drainage density Exner equation Groundwater model Hack's law Hjulström curve Hydrograph Hydrological model Hydrological transport model Infiltration (hydrology) Main stem Playfair's law Relief ratio River Continuum Concept Rouse number Runoff curve number Runoff model (reservoir) Stream gauge WAFLEX Wetted perimeter Volumetric flow rate
River engineering	Aqueduct Balancing lake Canal Check dam Dam Drop structure Daylighting Detention basin Erosion control Fish ladder Floodplain restoration Flume Infiltration basin Leat Levee River morphology Retention basin Revetment Riparian-zone restoration Stream restoration Weir
River sports	Canyoning Fly fishing Rafting River surfing Riverboarding Stone skipping Triathlon Whitewater canoeing Whitewater kayaking Whitewater slalom
Related	Aquifer Aquatic toxicology Body of water Hydraulic civilization Limnology Riparian zone River valley civilization River cruise Sacred waters Surface water Wild river
Rivers by length Rivers by discharge rate Drainage basins Whitewater rivers Flash floods River name etymologies Countries without rivers

v t e Sediment transport
Water	Armored mud ball Coastal sediment transport Fluvial processes Bed load Suspended load Bed material load
Glacial	Glacial flour Glacial outwash Braided river Moraine Esker Drumlin
Hillslope	Soil creep Landslide
Aeolian	Dune

Description

Formation

Occurrences

See also

References

Further reading

External links

Epstein Files Full PDF

Description

Formation

Occurrences

See also

References

Further reading

External links