Rivers Profiles Landforms Higher Geography The Hydrosphere River
- Slides: 47
Rivers: Profiles & Landforms Higher Geography The Hydrosphere
River Profile Source of river Upper Course Middle Course Lower Course
River speed Fastest? ?
Reality ü Landscapes have been modified by ice. ü Waterfalls and rapids interrupt smooth profiles.
Upper Course Lower Course
Contrasting river landforms from source to mouth Channel features Valley features Long profile
Upper Course - Channel features • River channel is rocky. • Covered with various shapes and sizes of boulder. • Discharge is low. • Under flood conditions rivers energy is expended on vertical erosion with hydraulic action and corrosion processes at work. • Potholes may form.
Vertical erosion
Pothole formation
Upper Course - Valley features • Valley sides are steep and form a ‘V’ shaped cross section. • Interlocking spurs. V shaped valley Steep sides Zig-zag bends (interlocking spurs)
V – shaped valley Form due to a combination of the following processes: Vertical erosion by the river itself. Physical weathering (eg: frost action) which provides debris to move down slope. Mass movement (inc: soil creep & landslides) to move debris down slope.
Interlocking spurs River flows around interlocking spurs
Upper Course – Long Profile • Generally the gradient is steep and the profile is uneven, particularly where waterfalls and rapids form.
Waterfall formation Soft rock is easy to erode, but the hard rock is resistant. So over time a ledge develops. Hard Rock – Lava Soft Rock – Sandstone or Conglomerates
Waterfall formation The water rushes over the ledge and erodes a plunge pool by abrasion and hydraulic action. Hard Rock – Lava Soft Rock – Sandstone or Conglomerates
Waterfall formation The ledge collapses into the plunge pool, where the debris helps to speed up the erosion. Hard Rock – Lava Soft Rock – Sandstone or Conglomerates
Waterfall formation The process is repeated and the waterfall gradually retreats upstream, carving out a gorge. Hard Rock – Lava Soft Rock – Sandstone or Conglomerates
WATERFALL RETREATS. UPSTREAM. . . OVERHANG UNDERCUTTING OF SOFT ROCK PLUNGE POOL
Formation of rapids Resistant rock Less Resistant Rock
Middle Course - Channel features • Channel is now wider and has smoother banks and bed compared to the upper course.
Middle Course - Valley features • River erosional energy is now increasingly expended horizontally rather than vertically. • Lateral erosion by the river’s meanders broadens the valley floor into a narrow flood plain. • Meanders gradually shift their course downstream.
Middle Course 1
Middle Course 2
Meanders A meander starts as a slight bend: Water flows faster on the outer curve of the bend (more energy), and slowest on the inner curve (less energy). So the outer bank gets eroded while material is deposited at the inner bank. Over time the outer bank gets worn away (river cliff) and the inner one builds up (river beach). The bend grows into a meander.
Meanders (refer to previous notes and diagrams) • Alternating series of irregularities develop • Pools – deeper stretches of slow moving water • Riffles – shallower section of faster flow, flowing above coarser material • River develops a winding or sinuous course • Faster flow on outer bend results in erosion and formation of River Cliff • Slower flow on inside of bend results in deposition and formation of Slip-off Slope
Meanders • Meanders develop and migrate laterally and downstream • Helicoidal flow further assists meander formation and transports sediment from river cliff to the slip-off slope on the inside of the next bend.
MEANDERS Meanders Possible break through point Most erosion on the outside of the bend. . Fastest flow Flood plain Possible ox-bow lake
Meanders
Middle Course - Profile
Middle Course - Profile • Gradient is now less steep. • Overall the profile is smooth – but an outcrop of resistant rock could still cause a waterfall.
Lower Course - Channel features • The channel is now at its broadest and deepest. • Bedload is carried entirely in suspension and is solution. • Deposition now dominates – particularly during floods. • Erosion also occurs – in the formation of meanders
Lower Course – Valley features • Thanks to lateral erosion the valley sides may now be several kilometres away. • Typically it may also contain the following features: Floodplain & natural levées Braided channels Meanders Oxbow lakes Estuaries and deltas
Lower Course
Natural levées • As the river floods, sediment is dropped over all the flooded areas but most falls along the river channel itself. • This sediment raises the height of the banks is flooding occurs regularly • Levees themselves do not prevent flooding because as the banks are raised, more sediment is dropped on the river bed, raising the water level.
Gentle valley sides River is actually flowing above The floodplain !! Flat floodplain Layers of silt Deposited during floods Levees is often artificially strengthened Coarse material Forms natural levees
Braided channels • Formed by the choking of the main channel by the deposition of a considerable amounts of the river load. • The channel splits into several smaller channels which flow around fresh ‘islands’ of deposited material before rejoining.
Braided channels
Braided channels
Ox-bow lakes Downstream migration of meanders produce pronounced meander loops which may form ox-bow lakes during flood conditions 1 Lateral erosion on outside of bends of pronounced meander 2 Narrow neck of meander gradually becomes narrower 3 Neck is cut through by river during floods and river forms new straighter channel 4 Cut-off is sealed by deposition 5 Ox-bow lake begins to silt up (Core Higher, P 65, Fig 3. 36)
Oxbow lakes An Oxbow lake starts as a meander. During a flood the river cuts across the meander, forming a new channel. Sediment is deposited along the sides of the new channel. The loops gets sealed off and an oxbow lake forms. The water in it becomes stagnant. The lake will remain sealed of until either the river floods into it or it dries out.
Oxbow lakes
NARROW MEANDER NECK FUTURE OX-BOW LAKE
Estuaries and deltas • An estuary is where a river meets the sea (it is tidal). • Deltas are essentially the seaward extension of the floodplain and form where tides are too weak to remove deposit sediment.
Team work and Alloa
Rivers on OS Maps tributaries V shaped valley Steep Valley sides meander ox-bow lake Flood plain
- Why are some rivers in texas called “wrong way” rivers?
- Oxbow lake definition
- Ecec salt river
- I am the river and the river is me
- Tukwila
- Brown earth soil profile diagram
- Brown earth soil profile diagram
- Advanced higher geography understanding standards
- Understanding standards higher english
- Interlocking spurs diagram
- River restoration definition geography
- River capture in geography
- Hydrosphere defintion
- Images of hydrosphere
- Thermal energy transfer
- Characteristics of hydrosphere
- Hydrosphere
- Hydrosphere layer
- Geosphere
- Biosphere
- Hydrosphere
- Whats hydrosphere
- Stream load
- Hydrosphere unit test answers
- How does capillary action allow water to climb up straw
- Four spheres of the earth poster
- Geosphere drawing
- How does biosphere interact with hydrosphere
- What is biosphere and geosphere
- Ocean zones graphic organizer
- Hydrosphere
- Hydrosphere includes *
- The structure of the hydrosphere
- Hydrosphere pictures
- The hydrosphere and lithosphere meet
- How is water distributed in the hydrosphere
- Earth systems
- Geosphere examples
- The hydrosphere includes
- Zimbabwe biomes
- Chapter 9 net present value and other investment criteria
- Profiles of the gifted and talented
- Onf profile
- Asee profiles
- Mining company profiles
- Npv profiles
- Welding discontinuities and defects
- Aitsl leadership profiles