ENVIRONMENTAL SCIENCE - PowerPoint PPT Presentation

About This Presentation
Title:

ENVIRONMENTAL SCIENCE

Description:

ENVIRONMENTAL SCIENCE 13e CHAPTER 12: Geology and Nonrenewable Mineral – PowerPoint PPT presentation

Number of Views:272
Avg rating:3.0/5.0
Slides: 58
Provided by: JohnSo95
Category:

less

Transcript and Presenter's Notes

Title: ENVIRONMENTAL SCIENCE


1
ENVIRONMENTAL SCIENCE
13e
CHAPTER 12Geology and Nonrenewable Mineral
2
Core Case Study The Real Cost of Gold
  • Two wedding rings 6 tons of mining waste
  • Gold mining pollutes air and water
  • Toxic cyanide used to mine gold
  • Gold mining harms wildlife

3
Fig. 12-1, p. 273
4
12-1 What Are the Earths Major Geological
Processes and Hazards?
  • Concept 12-1 Dynamic processes move matter
    within the earth and on its surface and can cause
    volcanic eruptions, tsunamis, and earthquakes.

5
The Earth Is a Dynamic Planet
  • What is geology?
  • Earths internal structure
  • Core
  • Mantle
  • Asthenosphere
  • Crust
  • Lithosphere

6
Plate Tectonics
  • Tectonic plates
  • Divergent plate boundaries
  • Convergent boundaries
  • Transform fault boundaries

7
Folded mountain belt
Volcanoes
Abyssal floor
Oceanic ridge
Trench
Abyssal floor
Craton
Abyssal hills
Abyssal plain
Oceanic crust (lithosphere)
Abyssal plain
Continental shelf
Continental slope
Continental rise
Continental crust (lithosphere)
Mantle (lithosphere)
Mantle (lithosphere)
Mantle (asthenosphere)
Fig. 12-2, p. 275
8
Spreading center
Ocean trench
Oceanic tectonic plate
Oceanic tectonic plate
Collision between two continents
Plate movement
Plate movement
Subduction zone
Tectonic plate
Oceanic crust
Oceanic crust
Continental crust
Continental crust
Cold dense material falls back through mantle
Material cools as it reaches the outer mantle
Hot material rising through the
mantle
Mantle convection cell
Mantle
Two plates move towards each other. One is
subducted back into the mantle on a falling
convection current.
Hot outer core
Inner core
Fig. 12-3, p. 275
9
Fig. 12-4, p. 276
10
Fig. 12-5, p. 277
11
Volcanoes
  • Magma
  • Lava
  • Eruptions
  • Lava rock
  • Hot ash
  • Liquid lava
  • Gases

12
Extinct volcanoes
Eruption cloud
Ash Acid rain
Ash flow
Lava flow
Mud flow
Central vent
Landslide
Magma conduit
Magma reservoir
Solid lithosphere
Upwelling magma
Partially molten asthenosphere
Fig. 12-6, p. 277
13
Earthquakes
  • Stressed rocks shift or break
  • Seismic waves
  • Seismographs
  • Richter scale to measure amplitude
  • Tsunami

14
Two adjoining plates move laterally along the
fault line
Liquefaction of recent sediments causes buildings
to sink
Earth movements cause flooding in low-lying areas
Landslides may occur on hilly ground
Shock waves
Focus
Epicenter
Fig. 12-7, p. 278
15
Fig. 12-8, p. 279
16
Fig. 12-9, p. 279
17
Fig. 12-10, p. 280
18
Waves head inland causing damage in their path.
Earthquake in seafloor swiftly pushes water
upwards, and starts a series of waves
Waves move rapidly in deep ocean reaching speeds
of up to 890 kilometers per hour.
As the waves near land they slow to about 45
kilometers per hour but are squeezed upwards and
increased in height.
Undersea thrust fault
Upward wave
Bangladesh
India
Burma
Thailand
Malaysia
Sri Lanka
Earthquake
Sumatra
Indonesia
December 26, 2004, tsunami
Fig. 12-10, p. 280
19
12-2 How Are Earths Rocks Recycled?
  • Concept 12-2 The three major types of rock found
    in the earths crust are recycled very slowly by
    physical and chemical processes.

20
Rocks and Minerals
  • Minerals
  • Rock
  • Igneous
  • Sedimentary
  • Metamorphic
  • Rock cycle

21
Sedimentary Rocks
  • Sediments
  • Tiny particles of eroded rocks
  • Dead plant and animal remains
  • Transported by water, wind, or gravity
  • Pressure converts into rock
  • Sandstone
  • Shale
  • Coal some types

22
Igneous Rocks
  • Forms from magma
  • Can cool beneath earths surface
  • Granite
  • Can cool above earths surface
  • Lava rocks
  • Most of earths crust

23
Metamorphic Rocks
  • From preexisting rocks
  • Pressure
  • Heat
  • Chemically active fluids
  • Slate from shale
  • Marble from limestone

24
Erosion
Transportation
Weathering
Deposition
Igneous rock
Granite, pumice, basalt
Sedimentary rock
Sandstone, limestone
Heat, pressure
Cooling
Heat, pressure, stress
Magma (molten rock)
Melting
Metamorphic rock Slate, marble, gneiss, quartzite
Fig. 12-12, p. 282
25
12-3 What Are Mineral Resources and What Are the
Environmental Effects of Using Them?
  • Concept 12-3 Some minerals in the earths crust
    can be made into useful products, but extracting
    and using these resources can disturb the land,
    erode soils, produce large amounts of solid
    waste, and pollute the air, water, and soil.

26
Nonrenewable Mineral Resources (1)
  • Minerals
  • Mineral resources
  • Fossil fuels
  • Metallic
  • Nonmetallic
  • Reserves

27
Nonrenewable Mineral Resources (2)
  • Ore
  • High-grade ore
  • Low-grade ore
  • Examples of mineral resources
  • Aluminum
  • Iron used for steel
  • Copper
  • Gold
  • Sand and gravel

28
Fig. 12-13, p. 283
29
Fig. 12-14, p. 284
30
Extracting Mineral Deposits (1)
  • Surface mining
  • Overburden
  • Spoils
  • Open-pit mining

31
Extracting Mineral Deposits (2)
  • Strip mining
  • Area strip mining
  • Contour strip mining
  • Mountaintop removal
  • Subsurface mining

32
Fig. 12-15, p. 284
33
Undisturbed land
Overburden
Highwall
Coal seam
Overburden
Pit
Bench
Coal seam
Spoil banks
Fig. 12-16, p. 285
34
Harmful Environmental Effects of Mining
  • Disruption of land surface
  • Damage to forests and watersheds
  • Biodiversity harmed
  • Subsidence
  • Toxic-laced mining wastes
  • Acid mine drainage

35
Fig. 12-17, p. 285
36
Fig. 12-18, p. 286
37
Fig. 12-18, p. 286
38
Harmful Environmental Effects of Removing Metals
from Ores
  • Ore mineral desired metal
  • Gangue waste material
  • Smelting
  • Air pollution
  • Water pollution
  • Acidified nearby soils
  • Liquid and solid hazardous wastes

39
12-4 How Long Will Supplies of Nonrenewable
Mineral Resources Last?
  • Concept 12-4 Raising the price of a scarce
    mineral resource can lead to an increase in its
    supply, but there are environmental limits to
    this effect.

40
Uneven Distribution of Mineral Resources
  • Abundant minerals
  • Scarce minerals
  • Exporters and importers
  • Strategic metal resources
  • Economic and military strength
  • U.S. dependency on importing four critical
    minerals

41
Supplies of Mineral Resources
  • Available supply and use
  • Economic depletion
  • Five choices after depletion
  • Recycle or reuse
  • Waste less
  • Use less
  • Find a substitute
  • Do without

42
Market Prices Affect Supplies of Nonrenewable
Minerals
  • Supply and demand affect price
  • Not a free market in developed countries
  • Subsides, taxes, regulations, import tariffs
  • Prices of minerals dont reflect their true costs
  • Developing new mines is expensive and
    economically risky

43
Science Focus Nanotechnology
  • 100 nanometers or less
  • 1 nanometer 1 billionth of a meter
  • Widespread applications
  • Potential risks
  • Need for guidelines and regulations
  • Future applications

44
Case Study U.S. General Mining Law of 1872
  • Design Encourage exploration and mining
  • Mining claim can give legal ownership of land
  • Abused land used for other purposes
  • Low royalties to federal government
  • Leave toxic wastes behind
  • 32-72 billion est. to clean up abandoned mines

45
Fig. 12-19, p. 289
46
Mining Lower-grade Ores
  • Improved equipment and technologies
  • Limiting factors
  • Cost
  • Supplies of freshwater
  • Environmental impacts
  • Biomining
  • In-situ mining
  • Slow

47
Ocean Mining
  • Minerals from seawater
  • Hydrothermal deposits
  • Manganese-rich nodules
  • High costs
  • Ownership issues
  • Environmental issues

48
12-5 How Can We Use Mineral Resources More
Sustainably?
  • Concept 12-5 We can try to find substitutes for
    scarce resources, reduce resource waste, and
    recycle and reuse minerals.

49
Finding Substitutes for Scarce Mineral Resources
  • Materials revolution
  • Ceramics
  • Plastics
  • Fiber-optic glass cables
  • Limitations
  • Recycle and reuse
  • Less environmental impact

50
Using Nonrenewable Resources More Sustainably
  • Decrease use and waste
  • 3M Company
  • Pollution Prevention Pays (3P) program
  • Economic and environmental benefits of cleaner
    production

51
Fig. 12-20, p. 291
52
Case Study Industrial Ecosystems (1)
  • Mimic nature to deal with wastes biomimicry
  • Waste outputs become resource inputs
  • Recycle and reuse
  • Resource exchange webs

53
Case Study Industrial Ecosystems (2)
  • Reclaiming brownfields
  • Industrial ecology
  • Ecoindustrial revolution

54
Sludge
Local farmers
Pharmaceutical plant
Sludge
Greenhouses
Waste heat
Waste heat
Waste heat
Fish farming
Waste heat
Surplus natural gas
Oil refinery
Electric power plant
Fly ash
Surplus sulfur
Waste calcium sulfate
Surplus natural gas
Waste heat
Cement manufacturer
Sulfuric acid producer
Area homes
Wallboard factory
Fig. 12-21, p. 292
55
Three Big Ideas from This Chapter - 1
  • Dynamic forces that move matter within the earth
    and on its surface recycle the earths rocks,
    form deposits of mineral resources, and cause
    volcanic eruptions, earthquakes, and tsunamis.

56
Three Big Ideas from This Chapter - 2
  • The available supply of a mineral resource
    depends on how much of it is in the earths
    crust, how fast we use it, mining technology,
    market prices, and the harmful environmental
    effects of removing and using it.

57
Three Big Ideas from This Chapter - 3
  • We can use mineral resources more sustainably by
    trying to find substitutes for scarce resources,
    reducing resource waste, and reusing and
    recycling nonrenewable minerals.
Write a Comment
User Comments (0)
About PowerShow.com