Stream bed

A streambed or stream bed is the bottom of a stream or river and is confined within a channel or the banks of the waterway.^[1] Usually, the bed does not contain terrestrial (land) vegetation and instead supports different types of aquatic vegetation (aquatic plant), depending on the type of streambed material and water velocity. Streambeds are what would be left once a stream is no longer in existence. The beds are usually well preserved even if they get buried because the banks and canyons made by the stream are typically hard, although soft sand and debris often fill the bed. Dry, buried streambeds can actually be underground water pockets.^[1] During times of rain, sandy streambeds can soak up and retain water, even during dry seasons, keeping the water table close enough to the surface to be obtainable by local people.^[1]

The nature of any streambed is always a function of the flow dynamics and the local geologic materials. The climate of an area will determine the amount of precipitation a stream receives and therefore the amount of water flowing over the streambed. A streambed is usually a mix of particle sizes which depends on the water velocity and the materials introduced from upstream and from the watershed. Particle sizes can range from very fine silts and clays to large cobbles and boulders (grain size). In general, sands move most easily, and particles become more difficult to move as they increase in size. Silts and clays, although smaller than sands, can sometimes stick together, making them harder to move along the streambed.^[2] In streams with a gravel bed, the larger grain sizes are usually on the bed surface with finer grain sizes below. This is called armoring of the streambed.^[2]^[3]^[4]

The streambed is very complex in terms of erosion and deposition. As the water flows downstream, different sized particles get sorted to different parts of a streambed as water velocity changes and sediment is transported, eroded and deposited on the streambed.^[5] Deposition usually occurs on the inside of curves, where water velocity slows, and erosion occurs on the outside of stream curves, where velocity is higher.^[2] This continued erosion and deposition of sediment tends to create meanders of the stream. In streams with a low to moderate grade, deeper, slower water pools (stream pools) and faster shallow water riffles often form as the stream meanders downhill. Pools can also form as water rushes over or around obstructions in the waterway.^[2]

Under certain conditions a river can branch from one streambed to multiple streambeds.^[2] For example, an anabranch may form when a section of stream or river goes around a small island and then rejoins the main channel. The buildup of sediment on a streambed may cause a channel to be abandoned in favor of a new one (avulsion (river)). A braided river may form as small threads come and go within a main channel.^[6] The measurement of riverbed depths is called bathymetry.

Climate change

The intensity and frequency of both drought and rain events are expected to increase with climate change.^[7]^[8] Floods, or flood stage, occur when a stream overflows its banks. In undisturbed natural areas, flood water would be able to spread out within a floodplain and vegetation of either grassland or forest, would slow and absorb peak flows. In such areas, streambeds should remain more stable and exhibit minimal scour. They should retain rich organic matter and, therefore continue to support a rich biota (river ecosystem). The majority of sediment washed out in higher flows is "near-threshold" sediment that has been deposited during normal flow and only needs a slightly higher flow to become mobile again. This shows that the streambed is left mostly unchanged in size and shape over time.^[9] In urban and suburban areas with little natural vegetation, high levels of impervious surface, and no floodplain, unnaturally high levels of surface runoff can occur. This causes an increase in flooding and watershed erosion which can lead to thinner soils upslope. Streambeds can exhibit a greater amount of scour, often down to bedrock, and banks may be undercut causing bank erosion. This increased bank erosion widens the stream and can lead to an increased sediment load downstream.^[10]

References

^ ^a ^b ^c "Below sandy, dry riverbeds: A medicine against drought". www.un-ihe.org. Retrieved 2023-06-08.
^ ^a ^b ^c ^d ^e Allan, David (2009). Stream Ecology: Structure and Function of Running Waters (2nd ed.). Dordrecht, The Netherlands: Springer. pp. |pages=36-43. ISBN 9781402055829.
^ Whiting, Peter J.; King, John G. (2003). "Surface particle sizes on armoured gravel streambeds: Effects of supply and hydraulics". Earth Surface Processes and Landforms. 28 (13): 1459–1471. Bibcode:2003ESPL...28.1459W. doi:10.1002/esp.1049.
^ Wilcock, Peter R.; DeTemple, Brendan T. (2005). "Persistence of armor layers in gravel-bed streams". Geophysical Research Letters. 32 (8). Bibcode:2005GeoRL..32.8402W. doi:10.1029/2004GL021772. ISSN 0094-8276.
^ Garcia, Marcelo; Parker, Gary (1991). "Entrainment of Bed Sediment into Suspension". Journal of Hydraulic Engineering. 117 (4): 414–435. doi:10.1061/(asce)0733-9429(1991)117:4(414).
^ Jerolmack, Douglas J.; Mohrig, David (2007). "Conditions for branching in depositional rivers". Geology. 35 (5): 463. Bibcode:2007Geo....35..463J. doi:10.1130/G23308A.1. ISSN 0091-7613.
^ Blöschl, Günter; Hall, Julia; Viglione, Alberto; Perdigão, Rui A. P.; Parajka, Juraj; Merz, Bruno; Lun, David; Arheimer, Berit; Aronica, Giuseppe T.; Bilibashi, Ardian; Boháč, Miloň; Bonacci, Ognjen; Borga, Marco; Čanjevac, Ivan; Castellarin, Attilio (2019). "Changing climate both increases and decreases European river floods". Nature. 573 (7772): 108–111. Bibcode:2019Natur.573..108B. doi:10.1038/s41586-019-1495-6. hdl:11585/740407. ISSN 1476-4687. PMID 31462777.
^ Marsooli, Reza; Lin, Ning; Emanuel, Kerry; Feng, Kairui (2019-08-22). "Climate change exacerbates hurricane flood hazards along US Atlantic and Gulf Coasts in spatially varying patterns". Nature Communications. 10 (1): 3785. Bibcode:2019NatCo..10.3785M. doi:10.1038/s41467-019-11755-z. ISSN 2041-1723. PMC 6706450. PMID 31439853.
^ Phillips, Colin B.; Jerolmack, Douglas J. (2016). "Self-organization of river channels as a critical filter on climate signals". Science. 352 (6286): 694–697. Bibcode:2016Sci...352..694P. doi:10.1126/science.aad3348. PMID 27151865.
^ US EPA, ORD (2015-12-23). "Urbanization - Stormwater Runoff". United States Environmental Protection Agency. Retrieved 2023-06-08.

External links

Media related to Stream beds at Wikimedia Commons

[:1-1] "Below sandy, dry riverbeds: A medicine against drought". www.un-ihe.org. Retrieved 2023-06-08.

[:0-2] Allan, David (2009). Stream Ecology: Structure and Function of Running Waters (2nd ed.). Dordrecht, The Netherlands: Springer. pp. |pages=36-43. ISBN 9781402055829.

[3] Whiting, Peter J.; King, John G. (2003). "Surface particle sizes on armoured gravel streambeds: Effects of supply and hydraulics". Earth Surface Processes and Landforms. 28 (13): 1459–1471. Bibcode:2003ESPL...28.1459W. doi:10.1002/esp.1049.

[4] Wilcock, Peter R.; DeTemple, Brendan T. (2005). "Persistence of armor layers in gravel-bed streams". Geophysical Research Letters. 32 (8). Bibcode:2005GeoRL..32.8402W. doi:10.1029/2004GL021772. ISSN 0094-8276.

[5] Garcia, Marcelo; Parker, Gary (1991). "Entrainment of Bed Sediment into Suspension". Journal of Hydraulic Engineering. 117 (4): 414–435. doi:10.1061/(asce)0733-9429(1991)117:4(414).

[6] Jerolmack, Douglas J.; Mohrig, David (2007). "Conditions for branching in depositional rivers". Geology. 35 (5): 463. Bibcode:2007Geo....35..463J. doi:10.1130/G23308A.1. ISSN 0091-7613.

[7] Blöschl, Günter; Hall, Julia; Viglione, Alberto; Perdigão, Rui A. P.; Parajka, Juraj; Merz, Bruno; Lun, David; Arheimer, Berit; Aronica, Giuseppe T.; Bilibashi, Ardian; Boháč, Miloň; Bonacci, Ognjen; Borga, Marco; Čanjevac, Ivan; Castellarin, Attilio (2019). "Changing climate both increases and decreases European river floods". Nature. 573 (7772): 108–111. Bibcode:2019Natur.573..108B. doi:10.1038/s41586-019-1495-6. hdl:11585/740407. ISSN 1476-4687. PMID 31462777.

[8] Marsooli, Reza; Lin, Ning; Emanuel, Kerry; Feng, Kairui (2019-08-22). "Climate change exacerbates hurricane flood hazards along US Atlantic and Gulf Coasts in spatially varying patterns". Nature Communications. 10 (1): 3785. Bibcode:2019NatCo..10.3785M. doi:10.1038/s41467-019-11755-z. ISSN 2041-1723. PMC 6706450. PMID 31439853.

[Phillips&Jerolmack20162-9] Phillips, Colin B.; Jerolmack, Douglas J. (2016). "Self-organization of river channels as a critical filter on climate signals". Science. 352 (6286): 694–697. Bibcode:2016Sci...352..694P. doi:10.1126/science.aad3348. PMID 27151865.

[10] US EPA, ORD (2015-12-23). "Urbanization - Stormwater Runoff". United States Environmental Protection Agency. Retrieved 2023-06-08.

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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

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References

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