This document discusses key concepts about rivers and drainage systems. It begins by explaining how streams form from surface runoff and how drainage networks develop distinct patterns influenced by geology. It then describes characteristics of permanent and ephemeral rivers, including variations in discharge, channel velocity, and sediment transport. The document outlines how river characteristics change longitudinally from headwaters to mouth. Finally, it discusses additional fluvial landforms and processes such as meanders, deltas, and flooding.
3. Streamflow
• Stream/River – water flow down channels
• Runoff – water flow over land surface
• Stream runoff is crucial for humans:
• Drinking water
• Transportation
• Waste disposal
• Recreation
• Commerce
• Irrigation
• Energy
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4. Streamflow
• Stream flow/runoff also causes many problems
• Flooding destroys lives and property
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5. Streamflow
• Stream flow/ runoff is an important geologic age
• Flowing water…
• Erodes, transports, deposits sediments
• Sculps landscapes
• Transfers mass from continents to oceans
• Earth: only planet in solar system with liquid water
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7. Forming Streams
• Streamflow begins as water is added to the surface
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8. Forming Streams
Streamflow begins as moving sheetwash
thin surface water layer
moves down steepest slope
erodes substrate
• Sheetwash erosion creates
tiny channels (rills)
• Rills coalesce & deepen
into channels.
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9. Forming Streams
• Scouring can mark entry into the channel
• Rapid erosion lengthens channel upslope
• Process is called headward erosion
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10. Forming Streams
• Over time, channels merge.
• Smaller tributaries join larger trunk stream
• A drainage network – array of linked channels
• They change over time
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12. Drainage Networks
• Drainage networks form geometric patterns
• Patterns reflect geology and landscape form
• Several common drainage patterns:
1. Dendritic – branching, “treelike”- due to uniform material
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13. Drainage Networks
• Common drainage patterns:
2. Radial – form a point uplift (e.g. volcano)
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14. Drainage Networks
• Common drainage patterns:
3. Rectangular – controlled by jointed rocks
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15. Drainage Networks
• Common drainage patterns:
4. Trellis (garden) – due to alternating resistant/weak rocks
common in fold-trust belts
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16. A Drainage Basin
• Land area that drains into a specific trunk stream
Also called catchment or watershed
• Divides are boundaries that separate drainage basins
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17. Drainage Divides
• Watersheds exist
across scales.
• Tiny tributaries
• Continental rivers
• Large watersheds…
• Feed large rivers
• Section continents
• Continental divides
separate flow to
different oceans
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19. Permanent vs. Ephemeral
• Permanent streams • Ephemeral streams
• Water flows all year. • Do not flow all year.
• At or below the water table. • Above the water table.
• Humid or temperate. • Dry climates.
• Sufficient rainfall. • Low rainfall.
• Lower evaporation. • High evaporation.
• Discharge varies seasonally. • Flow mostly during rare
flash floods.
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20. Discharge
• Amount of water flowing in a channel
• Water volume passing a point per unit time
• Cubic meters per second (m3/s)
• Given bycross-sectional area (Ac) x flow velocity
• Varies seasonally due to precipitation and runoff
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21. Channel Velocity
• Velocity is not uniform in the channel
• Friction slows water along edges
• Greater in wider, shallower streams
• Lesser in wider, shallower streams
• Magnitude determined by wetter perimeter
• Greater wetted perimeter, slower the velocity
• In straight channels, highest velocity in center
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22. Channel Velocity
• Velocity is not uniform within a channel
• Max. velocity near outside in bending channels
• Outside is preferentially scoured and deepened (cut bank)
• Inside is locus of desposition (point bar) due to reduced velocity
• Deepest part is called the thalweg
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23. Channel Velocity
• Velocity is not uniform in all areas of a channel
• Stream flow is turbulent
• Chaotic and erratic
• Turbulence caused by…
• Flow obstructions
• Shear in water
• Eddies scour channel
bed.
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24. Erosion Processes
• River flow does work
• Energy imparted is derived from gravity
• Do work by converting potential to kinetic energy
• Erosion is maximized during floods
• Large water volumes, high velocities, abundant sediment
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25. Erosion Processes
• Stream erosion: scour, break abrade, dissovle material
1. Scouring – running water picks up sediment and moves it
2. Breaking & lifting – the force of moving water can…
break chunks off the channel bottom/walls
can lift rocks off the channel bottom
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26. Erosion Processes
3. Abrasion – sediment grains in flow “sandblast” rocks
• Exposed bedrock in channels gets polished smooth
• Gravel swirled by turbulent eddies drills holes
• Bowl-shaped depressions are called potholes
• Potholes are unusual, intricately sculpted
4. Dissolution – mineral matter dissolves in water
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27. Sediment Transport
• Sediment load – material moved by rivers
• 3 types:
1. Dissolved load – Ions from mineral weathering
2. Suspended load – fine particals (silt and clay) in the flow
3. Bed load – large articles roll, slide, bounce along bottom
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28. Sediment Transport
• Competence – maximum size transported
• Capacity – maximum load transported
• Change with discharge:
• High discharge – large cobbles and boulders may move
• Low discharge – large clasts are stranded
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29. Sediment Deposition
• When flow velocity decreases…
• Competence is reduced and sediment drops out
• Grain sizes are sorted by water.
• Sands are removed from gravels; muds from both.
• Gravels settle in channels.
• Sands drop out in near channel environments.
• Silts & clays drape floodplains away from channels.
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30. Sediment Deposition
• Sediment size tracks with river slope
• Coarsest particles typify steep slopes in headwaters
• Fine particles typify gentler slopes near the mouth
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31. Sediment Deposition
Fluvial (river) sediments are called alluvium
• Channels may have mid-channel bars
• Sands build up point bars inside channel bends
• A stream builds a delta upon entering a lake/ocean
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32. Longitudinal Changes
• Stream character changes with flow distances
• In profile, the gradient is a concave-up curve
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33. Longitudinal Changes
• Near stream headwaters…
• Gradient is steep, discharge is low
• Sediment sizes are course (large)
• Channels are straight, rocky
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34. Longitudinal Changes
• Toward the mouth (downstream end)…
• Gradient is low, higher discharges
• Smaller grain sizes typical
• Channels are larger, bend more
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36. Base Level Concept
Lowest point to which a stream
• Ultimate base level is sea level
• Streams cannot erode below sea level
• A lake serves as a local (or temporary) base level
• Base level changes cause stream to adjust
• Raising base level results in an increase in desposition
• Lowering base level accelerates erosion
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37. Valleys and Canyons
• Land far above base level is subject to down cutting
• Rapid down cutting creates eroded trough
• Valley – gently sloping trough sidewalls define a V-shape
• Canyon – steep trough sidewalls form cliffs
• Determined by rate of erosion vs. strength of rocks
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38. Stream Terraces
• Valleys store sediment when base level is stable/raised
• Stability, then renewed incision creates stream terraces
• Terraces are former, now abandoned, floodplains
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39. Rapids & Waterfalls
• Rapids are turbulent water with a rough surface
• Waterfalls are free-falling water columns
• Reflect geologic control:
• Flow over bedrock steps or large clasts
• Flow constriction (channel narrowing)
• Sudden increase in gradient
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40. Alluvial Fans
• Build at mountain front by river (or debris) flow
• Sediments rapidly dropped near stream source
• Sediments create a conical, fan-shaped structure
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41. Braided Streams
• Form where channels are choked by sediment
• Flow is forced around sediment obstructions
• Diverging - converging flow creates sand and gravel bars
• Bars are unstable, rapidly formed and eroded
• Flow occupies multiple channels across a valley
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42. Meandering Streams
• Channels can form looping curves
• Along lower river portion with low gradient
• Where streams travel over a broad floodplain
• When substrates are soft and easily eroded
• Meanders increase volume of water in the stream
• Meanders evolve
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43. Meandering Streams
• Max velocity swings back & forth across channels
• Fast water erodes cut back (outside of bend)
• Point bar (inside of bend) collects sediment
• Meanders change due to natural variation in...
• Thalweg (maximum depth) position and friction
• Get cutoff when sinuosity gets too severe (cut banks converge)
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44. Meandering Streams
• Meanders become more sinuous with time
• Cut bank erodes; point bar accretes.
• Curves become more pronounced
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45. Deltas
• Deltas form a river enters standing water (base level)
• Flow slws, loses competence; sediments drop out
• Channel divides into a fan of small distributaries
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46. Deltas
• Mississippi has a river-dominated bird’s foot delta
• Distinct lobes indicate past desposition centers
• River periodically switches course via avulsion
• River breaks through a levee upstream
• Establishes a shorter, steeper path to the Gulf of Mexico
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47. Drainage Evolution
• Streamflow is cause of most
Landscape changes
• Example:
•Upliftchanges base level
•Streams cut down
•Valleys widen; hills erode
•Landscape lowered to new base level
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48. Drainage Evolution
Stream piracy
• One stream captures flow from
another
• Results from headward erosion
• A stream with more vigorous
erosion (steeper gradient),
intercepts another stream
• Captured stream flows into the new
stream
• Below capture point, old stream
dries up
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49. Drainage Evolution
Drainage reversal
• Tectonic uplift can alter a river course
• South America used to drain westward
• Western uplift raised the Andes, changed Amazon flow to east
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50. Drainage Evolution
Antecedent drainages
• Tectonic uplift can raise ground beneath
established streams
• If erosion keeps pace with uplift, stream
will incise into uplift
• Called antecedent drainage
• If uplift rate exceeds incision, stream is
diverted around uplft
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51. Drainage Evolution
• Some antecedent streams have incised meanders
• Meanders initially develop on a low gradient
• Uplift raises landscape (drops base level_)
• Meanders incise into the uplifted
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52. Raging Waters
• During a flood…
• Flow exceeds water volume storage of a channel
• Velocity (thus, competence & capacity) increase
• Water leaves channel, drowns adjacent land
• Moving water & debris scour floodplains
• Water slows away from the thalweg, dropping sediment
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53. Raging Waters
• Numerous causes of floods:
• Torrential rainfall
• After soil pores have been filled by prior rainfalls
• Abrupt warm weather rapidly melts winter snow
• Failure of a natural/artifical dam
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54. Raging Waters
• Case history: Mississippi and Missouri Rivers, 1993.
• Spring 1993: long rainy season
• July 1993: flood waters invaded huge areas
• Covered 40,000 mi2.
• Flood lasted 79 days.
• 50 people died.
• 55,000 homes destroyed.
• $12 billion in damage.
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55. Raging Waters
• Seasonal floods recur on an annual basis.
• Monsoons – heavy tropical rains (ie on Indian subcontinent)
• Intense period of heavy summer rain
• Many people live in floodplain & delta plain settings.
• 1990 - monsoon killed 100,000 people in Bangladesh.
• 2008 – monsoon caused the Kosi river to avulse, displacing ~2.3 million
people in Nepal/India.
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56. Raging Waters
• Kosi River flood before and after.
• New channel width ~20 km!
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57. Raging Waters
• Kosi River flood before and after.
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58. Raging Waters
• Ancient floods: Ice-Age megafloods.
• 11 Ka, ice dams failed, releasing Glacial Lake Missoula
• Water scoured eastern Washington landscape
• Created “channeled scablands”
• Once of largest floods in geologic histroy
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59. Living with Floods
• People living in floodplains face hard choice
• Move or expect eventual catastrophic loss
• Land use changes may mitigate flood damage
• Establish floodways – places designed to transmit floods
• Remove people and structures from these places
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60. Living with Floods
• Flood risk borne by homeowners, insurance companies,
lenders, government agencies
• Use hydrologic data to produce flood ricks maps
• Maps allow agencies to manage risks
• Building in flood-prone settings is tightly regualted
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61. Living with Floods
• Flood risk is calculated as a probability
• Discharges are plotted against recurrence intervals
• On semi-log, this plots as a straight long
• Probability (% chance of occurrence) given discharge will happen
(determined by graph inspection)
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