1. Geology and Nonrenewable Mineral Resources
Chapter 12

2. Core Case Study: Nanotechnology
Bottom-up manufacturing
Widespread applications
Potential risks
Need for guidelines and regulations
Future applications

3. Nanosolar Cells
Fig. 12-1, p. 261

4. 12-1 What Are the Earth’s Major Geological Processes?
Concept Gigantic plates in the earth’s crust move very slowly atop the planet’s mantle, and wind and water move matter from place to place across the earth’s surface.

5. The Earth Is a Dynamic Planet
What is geology?
Earth’s internal structure
Core
Mantle
Crust

6. Plate Tectonics Tectonic plates Lithosphere Types of plate boundaries
Divergent
Convergent
Transform fault

7. Plate Tectonics and Natural Hazards
Earthquakes
Volcanoes
Tsunamis
Geologic recycling and biodiversity

8. Earth’s Crust and Upper Mantle

9. Abyssal floor Oceanic ridge Abyssal floor
Folded
mountain belt
Volcanoes
Abyssal
floor
Oceanic
ridge
Abyssal
floor
Trench
Abyssal hills
Craton
Abyssal plain
Oceanic crust
(lithosphere)
Abyssal plain
Continental
shelf
Continental
slope
Continental
rise
Continental crust
(lithosphere)
Mantle (lithosphere)
Mantle (lithosphere)
Figure 12.2: Major features of the earth’s crust and upper mantle. The lithosphere, composed of the crust and outermost mantle, is rigid and brittle. The asthenosphere, a zone in the mantle, can be deformed by heat and pressure.
Mantle (asthenosphere)
Fig. 12-2, p. 263

10. Plate Tectonics

11. Oceanic tectonic plate Oceanic tectonic plate
Spreading
center
Ocean
trench
Oceanic tectonic plate
Oceanic tectonic plate
Collision between two continents
Plate movement
Plate movement
Tectonic plate
Subduction zone
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
Figure 12.3: The earth’s crust is made up of a mosaic of huge rigid plates, called tectonic plates, which move around in response to forces in the mantle.
See an animation based on this figure at ThomsonNOW.
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. 264

12. Earth’s Major Tectonic Plates

13. Fig. 12-4, p. 265 EURASIAN PLATE NORTH AMERICAN ANATOLIAN PLATE PLATE
JUAN DE
FUCA PLATE
CHINA
SUBPLATE
CARIBBEAN
PLATE
PHILIPPINE
PLATE
AFRICAN
PLATE
ARABIAN
PLATE
PACIFIC
PLATE
SOUTH
AMERICAN
PLATE
NAZCA
PLATE
INDIA-AUSTRALIAN
PLATE
SOMALIAN
SUBPLATE
Figure 12.4: The earth’s major tectonic plates. The extremely slow movements of these plates cause them to grind into one another at convergent plate boundaries, move apart from one another at divergent plate boundaries, and slide past one another at transform plate boundaries.
Question: What plate are you riding on?
See an animation based on this figure at ThomsonNOW.
ANTARCTIC PLATE
Fig. 12-4, p. 265

14. The San Andreas Fault
Fig. 12-5, p. 265

15. External Earth Processes
Weathering
Physical
Chemical
Biological
Erosion
Rain, flowing water, wind
Glaciers

16. 12-2 What Are Minerals and Rocks and How Are Rocks Recycled?
Concept 12-2A Some naturally occurring materials in the earth’s crust can be extracted and processed into useful materials.
Concept 12-2B Igneous, sedimentary, and metamorphic rocks in the earth’s crust are recycled very slowly by geologic processes.

17. Nonrenewable Mineral Resources (1)
Minerals
Mineral resource
Fossil fuels
Metallic
Nonmetallic

18. Nonrenewable Mineral Resources (2)
Identified resources
Reserves
Potential impact of nanotechnology

19. Rocks and Minerals Rock Ore Rock cycle Igneous Sedimentary Metamorphic
High-grade ore
Low-grade ore
Rock cycle

20. The Rock Cycle

21. Weathering Igneous rock Sedimentary rock Granite, pumice, basalt
Erosion
Transportation
Weathering
Deposition
Igneous rock
Sedimentary rock
Granite, pumice,
basalt
Sandstone, limestone
Heat, pressure
Cooling
Heat, pressure,
stress
Magma
(molten rock)
Figure 12.6: Natural capital: the rock cycle is the slowest of the earth’s cyclic processes. Rocks are recycled over millions of years by three processes: melting, erosion, and metamorphism, which produce igneous, sedimentary, and metamorphic rocks. Rock from any of these classes can be converted to rock of either of the other two classes, or can be recycled within its own class (Concept 12-2B).
Question: What are three ways in which the rock cycle benefits your lifestyle?
Melting
Metamorphic rock
Slate, marble,
gneiss, quartzite
Fig. 12-6, p. 267

22. 12-3 What Are the Harmful Environmental Effects of Using Mineral Resources?
Concept Extracting and using mineral resources can disturb the land, erode soils, produce large amounts of solid waste, and pollute the air, water, and soil.

23. Environmental Impact of Using Mineral Resources (1)
High energy use
Disturb land
Erode soil
Produce solid waste

24. Environmental Impact of Using Mineral Resources (2)
Pollute air, water, and soil
Total impact may depend on grade of ore

25. Life Cycle of a Metal Resource

26. Surface mining Metal ore Separation of ore from gangue Smelting
Conversion
to product
Discarding
of product
Recycling
Figure 12.7: Life cycle of a metal resource. Each step in this process uses large amounts of energy and produces some pollution and waste.
Fig. 12-7, p. 268

27. Surface
mining
Metal ore
Separation
of ore from
gangue
Smelting
Discarding
of product
Recycling
Melting
metal
Conversion
to product
Figure 12.7: Life cycle of a metal resource. Each step in this process uses large amounts of energy and produces some pollution and waste.
Stepped Art
Fig. 12-7, p. 268

28. Environmental Effects of Using Mineral and Energy Resources
Fig. 12-8, p. 268

29. Extracting Mineral Deposits
Surface mining
Subsurface mining
Overburden
Spoils

30. Mining Methods Open-pit mining Strip mining Area strip mining
Contour strip mining
Mountaintop removal

31. Open-pit Mining
Fig. 12-9, p. 269

32. Strip Mining
Fig , p. 269

33. Contour Strip Mining

34. Undisturbed land Overburden Pit Bench Spoil banks Highwall Coal seam
Figure 12.11: Natural capital degradation: contour strip mining of coal used in hilly or mountainous terrain.
Spoil banks
Fig , p. 270

35. Mountaintop Mining
Fig , p. 270

36. Harmful Environmental Effects of Mining
Disruption of land surface
Subsidence
Toxic-laced mining wastes
Acid mine drainage
Air pollution

37. Harmful Environmental Effects of Removing Metals from Ores
Ore mineral – desired metal
Gangue – waste material
Smelting
Air polluting by-products
Chemical removal processes
Toxic holding ponds

38. 12-4 How Long Will Mineral Resources Last?
Concept An increase in the price of a scarce mineral resource can lead to increased supplies and more efficient use of the mineral, but there are limits to this effect.

39. Uneven Distribution of Mineral Resources
Abundant minerals
Scarce minerals
Exporters and importers
Strategic metal resources
Economic and military strength
U.S. dependency – four critical minerals
Sources?

40. Supplies of Mineral Resources
Available supply and use
Economic depletion
Six choices after depletion
Recycle, reuse, waste less, use less, find a substitute, do without
Depletion time

41. Depletion Curves for a Nonrenewable Resource

42. Present Depletion time A Depletion time B Depletion time C
Mine, use, throw away;
no new discoveries;
rising prices
Recycle; increase reserves
by improved mining
technology, higher prices,
and new discoveries B
Recycle, reuse, reduce
consumption; increase
reserves by improved
mining technology,
higher prices, and
new discoveries
Production C
Figure 12.13: Depletion curves for a nonrenewable resource (such as aluminum or copper) using three sets of assumptions. Dashed vertical lines represent times when 80% depletion occurs.
Present
Depletion
time A
Depletion
time B
Depletion
time C
Time
Fig , p. 272

43. Effect of Market Prices on Supplies of Nonrenewable Resources
Role of economics in mining
Standard economic theory
Limited free market in developed countries
Subsides, taxes, regulations, import tariffs
Economic problems of developing new mines

44. Mining Lower-grade Ores
Improved equipment and technologies
Limiting factors
Cost
Supplies of freshwater
Environmental impacts
Biomining
In-situ mining
Genetic engineering

45. Ocean Mining (1) Minerals from seawater Minerals for ocean sediments
Hydrothermal deposits
Manganese-rich nodules

46. Ocean Mining (2) Mining issues in international waters
Environmental issues

47. 12-5 How Can We Use Mineral Resources More Sustainably?
Concept We can try to find substitutes for scarce resources, recycle and reuse minerals, reduce resource waste, and convert the wastes from some businesses into raw materials for other businesses.

48. Finding Substitutes and Alternatives for Scarce Mineral Resources
Materials revolution
Ceramics and plastics
Limitations
Recycle and reuse
Less environmental impact

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

50. Sustainable Use of Nonrenewable Minerals
Fig , p. 275

51. Case Study: Industrial Ecosystems (1)
Mimic nature to deal with wastes – biomimicry
Waste outputs become resource inputs
Recycle and reuse
Resource exchange webs

52. Case Study: Industrial Ecosystems (2)
Reclaiming brownfields
Industrial ecology
Ecoindustrial revolution

53. An Industrial Ecosystem

54. Sulfuric acid producer
Sludge
Pharmaceutical plant
Local farmers
Sludge
Greenhouses
Waste
heat
Waste
heat
Waste
heat
Waste heat
Fish farming
Surplus natural gas
Oil refinery
Electric power plant
Fly ash
Surplus
sulfur
Waste
calcium
sulfate
Figure 12.15: Solutions: an industrial ecosystem in Kalundborg, Denmark, reduces waste production by mimicking a food web in natural ecosystems. The wastes of one business become the raw materials for another.
Question: Is there an industrial ecosystem near where you live or go to school? If not, why not?
Surplus
natural gas
Waste
heat
Cement manufacturer
Sulfuric acid producer
Wallboard factory
Area homes
Fig , p. 276

55. Sulfuric acid producer Surplus sulfur
Greenhouses
Waste
heat
Pharmaceutical plant
Waste
heat
Local farmers
Sludge
Fish farming
Waste
heat
Oil refinery
Waste heat
Surplus
natural gas
Electric power plant
Cement manufacturer
Fly ash
Sulfuric acid producer
Surplus
sulfur
Wallboard factory
Waste
calcium
sulfate
Surplus
natural gas
Area homes
Waste
heat
Stepped Art
Fig , p. 276

56. Animation: Geological Forces
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ANIMATION

57. Animation: Plate Margins
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58. Animation: Sulfur Cycle
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ANIMATION

59. Animation: Resources Depletion and Degradation
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ANIMATION

60. Video: Continental Drift
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61. Video: Asteroid Menace
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62. Video: Indonesian Earthquake
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63. Video: Tsunami Alert Testing
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64. Video: Mount Merapi Volcano Eruption
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VIDEO