Week 09 Slopes and Streams, Stream Landscapes PDF

Summary

This document provides lecture notes on physical geography, focusing on slopes, streams, and stream landscapes. It covers learning objectives, fluvial processes, sediment load, transportation, and landscape evolution theories.

Full Transcript

Physical Geography:
Slopes and Streams,
Stream Landscapes
10/28/2024-10/30/2024
PROFESSOR PETE PULEO

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Slopes and
Streams

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Learning Objectives
Describe the processes responsible for the erosion of slopes by water

Explain the concept of sediment yield from a stream’s drainage basin

Analyze the movement of sediment through river systems by processes
of erosion, transportation, and deposition

Discuss the river as a system

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Fluvial
Related to flowing water (rivers, streams, etc.)

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Fluvial Processes
Water flows from high elevation to low elevation

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6
 Rainsplash Erosion
Rain drops dislodge and scatter soils downslope

https://eos.com/blog/water-erosion/

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Sheet Erosion
Runoff channels carve surface soils/sediments
Precipitation rate > infiltration rate so water runs across surface

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 Vegetation and Erosion

https://graniteseed.com/blog/how-do-plants-help-prevent-erosion/

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River System
Trunk – Main part of
river system
(Mississippi River)

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River System
Tributary – Smaller
streams feeding into
the trunk (unlabeled
streams)

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River System
Drainage Basin or
Watershed – Full
network of trunk and
tributaries (green
area)

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Denudation
Overall lowering of the landscape elevation from weathering and
erosion

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 River Discharge
aka streamflow

https://www.researchgate.net/figure/Theory-of-Measurement-of-
Discharge_fig1_348845081

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 Erosion by Rivers
Hydraulic Action – Water dislodging and cracking rock material from
valley floor/walls

https://www.geo41.com/rivers-matu#river-processes-swiss-maturity

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 Erosion by Rivers
Abrasion – Mechanical erosion from rocks and sediment carried by the
river scraping against the valley floor/walls

https://www.geo41.com/rivers-matu#river-processes-swiss-maturity

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 Erosion by Rivers
Attrition – Rocks and sediments hitting each other and breaking into
smaller pieces

https://www.geo41.com/rivers-matu#river-processes-swiss-maturity

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 Erosion by Rivers
Corrosion/Dissolution – Rocks and minerals being dissolved by water
(solution on diagram)

https://www.geo41.com/rivers-matu#river-processes-swiss-maturity

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River Sediment Load
Dissolved load (not depicted), suspended load, bed load

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 River Sediment Transportation

https://www.alevelgeography.com/the-long-profile-changing-processes-types-
of-erosion-transportation-and-deposition/

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 River Sediment Characteristics
Transport Capacity – Max amount of sediment a stream can carry at a
given discharge (T = Transport Capacity, q = Discharge)

https://www.researchgate.net/figure/Measured-sediment-transport-capacity-
versus-flow-rate-a-and-measured-sediment_fig2_367407186

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 River Sediment Characteristics
Competence – The largest particle size a stream can set in motion

https://open.maricopa.edu/physicalgeology/chapter/13-3-stream-erosion-and-
deposition/

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 Sediment Yield
Mass of sediment leaving a stream
basin per year

https://www.researchgate.net/figure/Large-rivers-in-the-world-in-terms-of-
suspended-sediment-load-water-discharge-and_tbl1_229151197

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River Sediment Characteristics
Mississippi River - High transport capacity, medium competence

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 Stream Power
Stream’s ability to do work (like moving sediments)
Increases with discharge and slope

https://www.researchgate.net/figure/The-relationship-of-Tc-with-unit-stream-
power-on-six-slope-gradients_fig4_318161498

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 Base Level
The lowest elevation to which a river can erode

Ultimate (sea level) vs. local (elevation of nearby lakes, trunks, etc.)

http://www.sepmstrata.org/Terminology.aspx?id=base%20level

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Rivers and Energy

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Erosion by Rivers
Incision – Downward erosion of stream beds

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Deposition by Rivers
Aggradation – Sediment accumulation raising the level of a river valley’s
bed

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Delta
Where a stream reaches a coast or
lake, slows down, and deposits
sediment in a fan-like shape

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Alluvial Fan
Fan-shaped deposit of sediment

Associated with stream power reducing after leaving a confined valley

Streams are often seasonal

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Activity 1 Description
Work independently to answer the questions below. Then, discuss your
thoughts with a partner.

1) Draw a cross section of a stream. Draw and describe the major types
of river erosion (Hint: 4 types).
2) On another stream cross section, illustrate and describe how
sediments can move (hint: 4 types)

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Activity 1 Solution
1) Draw a cross section of a stream. Draw and describe the major types
of river erosion (Hint: 4 types).

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Activity 1 Solution
2) On the same drawing, illustrate and describe how sediments can
move (hint: 4 types)

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Stream
Landscapes

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Learning Objectives
Outline the effects of geologic structure, lithology, tectonics, and
climate on the patterns of stream erosion

Explain the important types of drainage networks and their origin

Briefly describe cases in which stream erosion overcomes the control of
geologic structure

Summarize the major theories of long-term landscape development

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 Factors Influencing Stream
Erosion
Climate Change Minimum annual streamflow change from 1940-2022
◦ Precipitation
◦ Temperature
◦ Vegetation type/cover

https://www.epa.gov/climate-indicators/climate-change-indicators-streamflow

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Factors Influencing Stream
Erosion
Lithology
◦ Resistance to physical weathering
◦ Resistance to chemical weathering
◦ Different slopes
◦ Different erosion rates

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Factors Influencing Stream
Erosion
Geologic Structure
◦ Hogback – Relatively steeply dipping ridge from less erodible layer sticking
out

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Factors Influencing Stream
Erosion
Geologic Structure
◦ Cuesta – Shallow dipping, erosion resistant rock layers forming an
asymmetrical ridge

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Factors Influencing Stream
Erosion
Geologic Structure
◦ Ridges and valleys

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Factors Influencing Stream
Erosion
Geologic Structure
◦ Domes

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Factors Influencing Stream
Erosion
Geologic Structure
◦ Faults

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Factors Influencing Stream
Erosion
Geologic Structure
◦ Plateaus, Mesa, Buttes from igneous rocks being resistant to weathering

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Drainage Density
Total length of stream channels in a given part of a drainage basin

Which has higher drainage density?

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Drainage Density
Total length of stream channels in a given part of a drainage basin

Which has higher drainage density?

B!

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Drainage Density
Higher drainage density -> higher rate of erosion

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Drainage Patterns
Radial – Radiate outward from a central high point (mountain peak,
volcano peak)

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Drainage Patterns
Annular – Around a high point but separated by ridges making the
drainage circle the peak

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Drainage Patterns
Trellis – Parallel layers of sloped/folded sedimentary rocks and resistant
ridges

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Drainage Patterns
Rectangular – Streams with right angles often associated with faults

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Drainage Patterns
Dendritic – Streams that resemble a tree's branching structure
Form on gently sloping, uniform bodies of rock
Most common drainage pattern

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Superimposed
Stream
Stream maintaining course
regardless of underlying structure

Forms horizontal surface beds that
overlay folded/faulted rock

Structural change predates stream

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Antecedent
Stream
Stream predating the ridge that
it erodes as it is lifted by
tectonics

Stream predates structural
change

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Stream Piracy
The capture of a segment of one stream by another
Dashed blue line was former river channel (before piracy)

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 Flood
Bankfull – Stream fills largest channel size, frequent, less damage
Overbank – Stream overflows its channel, infrequent, more damage

https://open.maricopa.edu/physicalgeology/chapter/13-3-stream-erosion-and-
deposition/

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Recurrence Interval
Average time between floods of a given magnitude in a given place

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Landscape Evolution Theories
Major ongoing area of research in geomorphology: how are regional
landscapes shaped?

The main theories have had mixed success when tested

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Landscape Evolution Theories
William Davis (1850-1934) suggested:

Uplift occurred and was followed by
erosion and downward slope
movement

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Landscape Evolution
Theories
Cycle of Erosion
◦ Young – Uplift followed by deep channels and
large plateaus
◦ Mature – More extensive channels, steep
slopes
◦ Old – Relatively flat plain (peneplain)

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Landscape Evolution Theories
German geographer Walther Penck
(1888-1923) suggested:

Uplift and weathering occur
simultaneously and slopes weather
backward, not downward

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Landscape Evolution
Theories
Slope Decline
(Davis)

Slope Retreat
(Penck)

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Activity 2 Description
Work independently to list and describe the factors that influence
stream erosion. Be as specific as you can. Then, discuss your thoughts
with a partner.

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Activity 2 Solution
Work independently to list and describe the factors that influence
stream erosion.

Precipitation amount influences discharge
Temperature and precipitation amount influence vegetation coverage
and type which controls how easily soil is eroded
Lithology influences resistance to physical weathering and resistance to
chemical weathering
Geologic structure influences the direction/gradient of slopes and which
areas are more susceptible to weathering and erosion

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Lecture Exam 2
(Weeks 5-9)

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