Lecture Outlines Power Point Chapter 5 Earth Science

Lecture Outlines Power. Point Chapter 5 Earth Science, 12 e Tarbuck/Lutgens © 2009 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their courses and assessing student learning. Dissemination or sale of any part of this work (including on the World Wide Web) will destroy the integrity of the work and is not permitted. The work and materials from it should never be made available to students except by instructors using the accompanying text in their classes. All recipients of this work are expected to abide by these restrictions and to honor the intended pedagogical purposes and the needs of other instructors who rely on these materials.

Earth Science, 12 e Running Water and Groundwater Chapter 5

Earth as a system: the hydrologic cycle v. Illustrates the circulation of Earth’s water supply v. Processes involved in the cycle • • • Precipitation Evaporation Infiltration Runoff Transpiration

The hydrologic cycle Figure 5. 3

Sources of Earth’s water Figure 5. 2

Running water v. Drainage basin • Land area that contributes water to a river system • A divide separates drainage basins

Drainage basins and drainage divides Figure 5. 4

Running water v. Streamflow • Factors that determine velocity • Gradient, or slope • Channel characteristics • Shape • Size • Roughness • Discharge – volume of water flowing in the stream (generally expressed as cubic feet per second)

Running water v. Upstream-downstream changes • Profile • Cross-sectional view of a stream • From head (source) to mouth • Profile is a smooth curve • Gradient decreases from the head to the mouth • Factors that increase downstream • Velocity • Discharge

Running water v. Upstream-downstream changes • Profile • Factors that increase downstream • Channel size • Factors that decrease downstream • Gradient, or slope • Channel roughness

Longitudinal profile of a stream Figure 5. 7

Running water v. The work of streams • Erosion • Transportation • Transported material is called the stream’s load • Dissolved load • Suspended load • Bed load

Running water v. The work of streams • Transportation • Load is related to a stream’s • Competence – maximum particle size • Capacity – maximum load • Capacity is related to discharge

Running water v. The work of streams • Transportation • Deposition • Caused by a decrease in velocity • Competence is reduced • Sediment begins to drop out • Stream sediments • Known as alluvium • Well-sorted deposits

Running water v. The work of streams • Transportation • Features produced by deposition • Deltas – exist in ocean or lakes • Natural levees – Form parallel to the stream channel • Area behind the levees may contain backswamps or yazoo tributaries

Formation of natural levees by repeated flooding Figure 5. 21

Running water v. Base level • Lowest point to which a stream can erode • Two general types • Ultimate – sea level • Temporary, or local • Changing causes readjustment of the stream – deposition or erosion

Adjustment of base level to changing conditions Figure 5. 15

Running water v. Stream valleys • Valley sides are shaped by • Weathering • Overland flow • Mass wasting • Characteristics of narrow valleys • V-shaped • Downcutting toward base level

Running water v. Stream valleys • Characteristics of narrow valleys • Features often include • Rapids • Waterfalls • Characteristics of wide valleys • Stream is near base level • Downward erosion is less dominant • Stream energy is directed from side to side

A narrow, V-shaped valley Figure 5. 17 A

Continued erosion and deposition widens the valley Figure 5. 17 B

A wide stream valley is characterized by meandering on a well-developed floodplain Figure 5. 17 C

Running water v. Stream valleys • Characteristics of wide valleys • Floodplain • Features often include • Meanders • Cutoffs • Oxbow lakes

Erosion and deposition along a meandering stream Figure 5. 10

A meander loop on the Colorado River Figure 5. 18

Formation of a cutoff and oxbow lake Figure 5. 11

Running water v. Drainage patterns • Networks of streams that form distinctive patterns • Types of drainage patterns • • Dendritic Radial Rectangular Trellis

Drainage patterns Figure 5. 22

Running water v. Floods and flood control • Floods are the most common geologic hazard • Causes of floods • Weather • Human interference with the stream system

Running water v. Floods and flood control • Engineering efforts • Artificial levees • Flood-control dams • Channelization • Nonstructural approach through sound floodplain management

Satellite view of the Missouri River flowing into the Mississippi River near St. Louis Figure 5. 23 top

Same satellite view during flooding in 1993 Figure 5. 23 bottom

Water beneath the surface (groundwater) v. Largest freshwater reservoir for humans v. Geological roles • As an erosional agent, dissolving by groundwater produces • Sinkholes • Caverns • An equalizer of streamflow

Water beneath the surface (groundwater) v. Distribution and movement of groundwater • Distribution of groundwater • Belt of soil moisture • Zone of aeration • Unsaturated zone • Pore spaces in the material are filled mainly with air

Water beneath the surface (groundwater) v. Distribution and movement of groundwater • Distribution of groundwater • Zone of saturation • All pore spaces in the material are filled with water • Water within the pores is groundwater • Water table – the upper limit of the zone of saturation

Features associated with subsurface water Figure 5. 26

Water beneath the surface (groundwater) v. Distribution and movement of groundwater • Distribution of groundwater • Porosity • Percentage of pore spaces • Determines storage of groundwater • Permeability • Ability to transmit water through connected pore spaces • Aquitard – an impermeable layer of material • Aquifer – a permeable layer of material

Water beneath the surface (groundwater) v. Features associated with groundwater • Springs • Hot springs • Water is 6– 9°C warmer than the mean air temperature of the locality • Heated by cooling of igneous rock • Geysers • Intermittent hot springs • Water turns to steam and erupts

Old Faithful geyser in Yellowstone National Park Figure 5. 29

Water beneath the surface (groundwater) v. Features associated with groundwater • Wells • Pumping can cause a drawdown (lowering) of the water table • Pumping can form a cone of depression in the water table • Artesian wells • Water in the well rises higher than the initial groundwater level

Formation of a cone of depression in the water table Figure 5. 31

Artesian systems Figure 5. 32

Water beneath the surface (groundwater) v. Environmental problems associated with groundwater • Treating it as a nonrenewable resource • Land subsidence caused by its withdrawal • Contamination

Water beneath the surface (groundwater) v. Geologic work of groundwater • Groundwater is often mildly acidic • Contains weak carbonic acid • Dissolves calcite in limestone • Caverns • Formed by dissolving rock beneath Earth’s surface • Formed in the zone of saturation

Water beneath the surface (groundwater) v. Geologic work of groundwater • Caverns • Features found within caverns • Form in the zone of aeration • Composed of dripstone • Calcite deposited as dripping water evaporates • Common features include stalactites (hanging from the ceiling) and stalagmites (growing upward from the floor)

Cave Features in Lehman Caves, Great Basin National Park, and Carlsbad Caverns National Park Figure 5. 38

Water beneath the surface (groundwater) v. Geologic work of groundwater • Karst topography • Formed by dissolving rock at, or near, Earth’s surface • Common features • Sinkholes – surface depressions • Sinkholes form by dissolving bedrock and cavern collapse • Caves and caverns • Area lacks good surface drainage

Features of karst topography Figure 5. 39 C

End of Chapter 5