Chapter 15 Geology and Nonrenewables
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Transcript Chapter 15 Geology and Nonrenewables
Geology and
Nonrenewable Minerals
Chapter 15
Environmental Effects of Gold Mining
Gold producers
South Africa
Australia
United States
Canada
Cyanide heap
leaching
Extremely toxic
to birds and
mammals
2000: Collapse of
a dam retaining a
cyanide leach
pond
Black Hills, S. Dakota
Earth’s Major Geological Processes
and Hazards
Gigantic plates in the earth’s crust move very slowly
atop the planet’s mantle, and wind and water move
the matter from place to place across the earth’s
surface.
Natural geological hazards such as earthquakes,
tsunamis, volcanoes, and landslides can cause
considerable damage.
The Earth Is a Dynamic Planet
What is geology?
Three major concentric zones of the earth
Core: solid inner part surrounded by a liquid core
Mantle: mostly solid rock
Including the asthenosphere: hot,partly melted rock
that flows and can be deformed like plastic
Crust
Continental crust
Oceanic crust: 71% of crust
Major Features of the Earth’s Crust
and Upper Mantle
The Earth beneath your feet is
moving…….
Convection cells, or currents : move large volumes of
rock and heat in loops within the mantle like gigantic
conveyer belts
Tectonic Plates: dozen or so huge rigid plates move
extremely slowly atop the denser mantle on hot, soft
rock in the underlying asthenosphere
Lithosphere: continental and oceanic crust and the
rigid, outermost part of the mantle
The Earth’s Crust Is Made Up of a Mosaic
of Huge Rigid Plates: Tectonic Plates
The Earth’s Major Tectonic Plates
EURASIAN PLATE
JUAN DE
FUCA PLATE
NORTH
AMERICAN
PLATE
CARIBBEAN
PLATE
ANATOLIAN
PLATE
CHINA
SUBPLATE
AFRICAN
PLATE
PACIFIC
PLATE
COCOS
PLATE
NAZCA
PLATE
Divergent plate boundaries
PACIFIC
PLATE
SOUTH
AMERICAN
PLATE
SOMALIAN
SUBPLATE
SCOTIA
PLATE
PHILIPPINE
PLATE
ARABIAN
PLATE INDIA
PLATE
AUSTRALIAN
PLATE
ANTARCTIC PLATE
Convergent plate
boundaries
Transform faults
Fig. 14-4, p. 347
The Earth beneath your feet is
moving ….
Three types of boundaries between plates
Divergent plates –plates move apart
Magma – flows up through the resulting cracks
Oceanic ridge – some of which have higher peaks and deeper canyons than
earth’s continents
Convergent plates – oceanic plate collides with a continental plate,
Subduction: the latter rides up over the denser oceanic plate and pushes it
down into the mantle
Subduction zone: area where collision and subduction takes place
Trench : forms at the boundary between the 2 converging plates
Transform fault e.g. San Andreas fault: where plates slide and grind past
one another along a fracture. Most located on the ocean floor
The San Andreas Fault as It Crosses Part
of the Carrizo Plain in California, U.S.
Some Parts of the Earth’s Surface
Build Up and Some Wear Down
Internal geologic processes
Generated by heat from the earth’s interior ,generally
build up the earth’s surface in the form of continental
and oceanic crust including mountains and volcanoes
External geologic processes
Weathering : driven directly or indirectly by energy
from the sun(mostly in the form of flowing water and
wind)
Physical, Chemical, and Biological : soil
Erosion
Wind
Flowing water
Human activities
Glaciers
Weathering: Biological, Chemical,
and Physical Processes
Volcanoes Release Molten Rock
from the Earth’s Interior
Volcano: magma reaches the earth’s surface through a..
Fissure: central vent or a long crack
Magma
Lava: magma that reaches the earth’s surface. Debris ranging from large
chunks of larva rock to glowing hot ash, liquid lava and gases such as
water vapor, carbon dioxide and sulfur dioxide . Much of the world’s
volcanic activity is concentrated along the boundaries of the earth’s
tectonic plates
1980: Eruption of Mount St. Helens
1991: Eruption of Mount Pinatubo: cooled the earth’ average temperature for
15 months
Benefits of volcanic activity: highly fertile soil, creates outstanding landforms
(Crater Lake in Oregon)
Creation of a Volcano
Earthquakes Are Geological
Rock-and-Roll Events
Earthquake
Seismic waves
Focus
Epicenter
Magnitude
Amplitude
Richter scale
Insignificant: <4.0
Minor: 4.0–4.9
Damaging: 5.0–5.9
Destructive: 6.0–6.9
Major: 7.0–7.9
Great: >8.0
Foreshocks and aftershocks
Primary effects of earthquakes: shaking, permanent
vertical or horizontal displacement of the ground
Major Features and Effects of an
Earthquake
Areas of Greatest Earthquake
Risk in the United States
Areas of Greatest Earthquake
Risk in the World
Earthquakes on the Ocean Floor
Can Cause Huge Waves Called
Tsunamis
Tsunami, tidal wave : generated when part of the ocean
floor suddenly rises or drops. Usually occurs offshore in
subduction zones.
Detection of tsunamis: by ocean buoys, pressure
recorders on the ocean floor which measures changes in
water pressure as the waves pass over it; data relayed via
satellites tsunami warning systems
December 2004: Indian Ocean tsunami
Magnitude of 9.15
Role of coral reefs and mangrove forests in reducing
death toll
Formation of a Tsunami and Map of
Affected Area of Dec 2004 Tsunami
Shore near Banda Aceh,Gleebruk
in Indonesia before and after
tsunami
Before :June 23, 2004
After: December 28, 2004
Gravity and Earthquakes Can
Cause Landslides
Mass wasting: detached or loose rock, soil and mud
to slide down steep slopes near the shores of oceans
or lakes
Slow movement
Fast movement
Rockslides
Avalanches
Mudslides : 1970 – Peru, buried the town of Yungay
and killed 17,000 people
Effect of human activities on such geological events:
forest clearing, road building , crop growing, building
houses
Earth’s Rocks are Recycled……..
The three major types of rocks found in the earth’s
crust—sedimentary, igneous, and metamorphic—are
recycled very slowly by the process of erosion,
melting, and metamorphism.
There Are Three Major Types of
Rocks
Earth’s crust
• Composed of minerals and rocks
Three broad classes of rocks, based on formation
Sedimentary
Igneous
Sandstone
Granite
Shale
Lava rock
Dolomite
Metamorphic
Slate
Anthracite
Lignite
Slate
Bituminous coal
Marble
The Earth’s Rocks Are Recycled
Very Slowly
Rock cycle: the
interaction of
physical and
chemical
processes that
change rocks
from one type to
another. Slowest
of the earth’s
cyclic processes
What Are Mineral Resources?
Naturally occurring materials in the earth’s crust that can
be extracted and made into useful products in processes
that provide economic benefits and jobs.
100 minerals:
fossil fuels(coal)
metallic(aluminum, iron, copper)
non-metallic(sand, gravel, limestone, salt, precious gems)
Mineral deposit – area in which a particular mineral is
concentrated.
Ore – metal-yielding material; contains 2 parts: the ore mineral
(metal) and waste mineral material (gangue)
High-grade ore – large amount of desired metal
Low-grade ore – small amount of the desired resource
Removing Metals from Ores
Nonrenewable – takes so long to be produced
Ore extracted by mining
Ore mineral = desired metal
Gangue - waste material. Removing the gangue from the ores
produces tailings. Particles of toxic metals blown by the wind
or leached by rainfall can contaminate surface water and
groundwater.
Smelting – heating ore in order to separate desired metals.
Without proper equipment, releases sulfur dioxide and
suspended particles, damage vegetation and acidify soils
Extracting, Processing, Using Nonrenewable
Mineral and Energy Resources
Life Cycle of a Metal Resource
Mineral Use Has Advantages and
Disadvantages
Ads: Mine
and convert
minerals into
useful
products
Disads: uses
enormous
amounts of
energy,
disturbs land,
erodes soil,
produces
solid waste,
air and water
pollution
Ways to Remove Mineral Deposits
Surface mining : shallow deposits removed
mechanized equipment strips away overburden(soil
and rock overlay), discarded as waste called spoils
Used to extract 90% of the nonfuel mineral and
rock resources and 6% of the coal
Type of surface mining used depends on
Resource
Local topography
Subsurface mining
Deep deposits removed
Used to extract coal and metal ores
Types of Surface Mining
Open Pit Mining - machines dig hole and remove ore
Strip Mining - earth movers strip overburden and power
shovels remove deposit
Contour Mining - mine coal on hilly terrain. Wall of dirt
left in front of a highly erodible bank of soil and rock called
highwall
Mountain Top Removal - Appalachian Mountains ,
draglines, explosives remove top of mountain to
expose seams
Open-Pit Mine in Western Australia
Undisturbed land
Overburden
Pit
Contour Strip Mining
in hilly areas
Bench
Spoil banks
Fig. 14-17, p. 357
Mountaintop Coal Mining in West
Virginia, U.S.
Mining has Harmful
Environmental Effects…….
Scarring and disruption of the
land surface
E.g., spoils banks
Large amounts of solid waste
(3/4th of all US solid waste)
Toxin-laced mining waste
deposited in areas other than
mining site .
Loss of rivers and streams –
1900 km have been buried
Subsidence - collapse of
land
Harmful Environmental Effects
Major pollution of water –
Acid mine drainage
Leaching of heavy metals
Oil and chemical spills
Highly toxic cyanide salts are used
to extract gold from its ore; leave
behind cyanide laden water
Effect on aquatic life –
pH change,
40% of all US watersheds
contaminated
Illegal Gold Mine
Environmental Effects of Gold Mining
Gold producers
South Africa
Australia
United States
Canada
Cyanide heap
leaching
Extremely toxic
to birds and
mammals
2000 - Collapse
of a dam retaining
a cyanide leach
pond
Black Hills, S. Dakota
Summitville Gold Mining Site in Colorado,
U.S.
The U.S. General Mining Law of
1872
Encouraged mineral exploration and mining of hardrock minerals on U.S. public lands
Developed to encourage settling the West (1800s)
Until 1995, land could be bought for 1872 prices
Companies must pay for clean-up now
LEGISLATION
Date
Name of
Legislation
1872
Mining Act
1920
Mineral Leasing
Act
1976 Resource
Conservation and
Recovery Acts
(RCRA)
What it Did
Governed prospecting and mining of
minerals on publicly owned land
Permitted the Bureau of Land
Management to grant leases for
development of deposits of coal,
phosphate, potash, sodium, sulfur, and
other leasable minerals on public
domain lands.
Regulated some mineral processing
wastes
LEGISLATION (cont.)
Date
Name of
Legislation
1977
Surface Mining
Control And
Reclamation Act
1980
Comprehensive
Environmental
Response,
Compensation, and
Liability Act
(CERCLA);
Superfund Act
What it Did
Established a program for regulating
surface coal mining and reclamation
activities.
It established mandatory standards for
activities on state and federal lands,
including a requirement that adverse
impacts on fish, wildlife, and related
environmental values be minimized.
It requires mining companies to restore
most surface-mined land.
Regulated damage done by mining
POSSIBLE REMEDIES FOR
MINIMIZING EFFECTS OF TOXINS
Buffer/neutralize with alkaline(basic) substances such as
limestone (calcium carbonate), sodium hydroxide
(NaOH), or ammonia.
Cover tailings to reduce contact with precipitation.
Sedimentation ponds/retention basins or ponds.
Bioremediation by sulfate-reducing bacteria.
Ecological Restoration of a Mining
Site in New Jersey, U.S.
POSSIBLE STEPS TO RESTORING
SURFACE-MINED LAND
Re-contouring/regrading land to its original
topography.
Replacing and/or adding topsoil/nutrients as
needed to improve soil quality or structure
Replanting
native vegetation
fast-growing species
early successional species
Monitor for 5 to 10 years
How Long Will Supplies of
Nonrenewable Mineral Resources
Last?
All mineral resources exist in finite amounts, and as we
get closer to depleting any mineral resource, the
environmental impacts of extracting it generally become
more harmful.
Relatively abundant deposits of iron and aluminum
(bauxite)
Scarce - manganese, chromium, cobalt, platinum
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.
Uneven Distribution of Minerals
Most of the nonrenewable mineral resources supplied
by
Canada
United States
8% of world population, consume
75% of the world’s key metals
Germany
China increasing consumption
Russia
South Africa - self sufficient in all key minerals,
largest producer of gold, chromium and platinum
Australia
Four Strategic Metal
Resources….
Manganese
Cobalt
Chromium
Platinum
US has little or no reserves of these metals which are
essential for the country’s economy and military
strength
May have to switch to “nano” materials
MINERAL PRODUCTION OF SOME
NON-FUEL MINERAL RESOURCES
Mineral
Bauxite (aluminum ore)
Copper
Iron ore
Phosphate rock (for fertilizer)
Zinc
2004 Production
(thousands of metric tons)
159,000
14,600
1,340,000
141,000
9,600,000
*High production rates lead to eventual depletion of the resources.
The Nanotechnology Revolution
Nanotechnology (tiny tech) - use carbon, oxygen and
silicone atoms to create everything from medicines, solar
cells to automobile bodies
Currently used in more than 400 items - odor eating
socks, wrinkle –free clothes, cosmetics, sun screens
Nanoparticles
Are they safe?
Investigate potential ecological, economic, health, and
societal risks
Develop guidelines for their use until more is known
about them
Economic Depletion of Nonrenewable Mineral Resources
Future supply depends on
Actual or potential supply of the mineral
Rate at which it is used
When it becomes economically depleted
Recycle or reuse existing supplies
Waste less
Use less
Find a substitute
Do without
MINERAL ORES AND YEARS OF
SUPPLY
Mineral
Bauxite (aluminum ore)
Copper
Years of Supply
152
32
Iron ore
Nickel
Zinc
105
41
22
*The increased demand for manufactured goods means we need to
extract more and more raw materials from the Earth.
Depletion Curves for a Nonrenewable
Resource
Depletion time - time it
takes to use up
approximately 80% of the
reserves of a mineral at a
given rate of use
Market Prices Affect Supplies of
Nonrenewable Minerals
Subsidies and tax breaks to mining companies keep
mineral prices artificially low
Does this promote economic growth and national
security?
Scarce investment capital hinders the development of
new supplies of mineral resources
Is Mining Lower-Grade Ores the
answer?
Factors limit the mining of lower grade ores
increased cost of mining
limited availability of fresh water
environmental impacts of increased land disruption, waste material
and pollution produced during mining and processing
Use microorganisms that can extract minerals “in-place” or “insitu” mining.
Biomining - genetic engineering techniques used to produce
bacteria that can be used to extract a particular metal without
disturbing the surrounding environment
Extend Supplies by Getting More
Minerals from the Ocean…
Mineral resources dissolved in the ocean-very low
concentrations, requires more energy and money
than they are worth
Only magnesium, bromine and sodium chloride are
abundant enough to be extracted profitably
Deposits of minerals in sediments along the shallow
continental shelf and near shorelines - sand,
gravel,phosphates,sulfur,tin,copper,iron,tungsten,silver,
titanium,platinum,diamonds
Extend Supplies by Getting More
Minerals from the Ocean
Hydrothermal ore deposits : sulfides, zinc, silver, copper
precipitate out and build up as mineral deposits
currently costs too much to extract,
disputes over ownership
Metals from the ocean floor - potato sized manganese
nodules, cover 25-50% of the Pacific ocean floor
Effect of mining on aquatic life
Environmental impact - sea bed mining ,less impact than land (??)
How Can We Use Mineral Resources
More Sustainability?
Find substitutes for some scarce mineral resources
materials revolution : silicon, ceramics, plastics
houses made of styrofoam sprayed with ceramic spray called
Grancrete, reduces use of timber
high strength plastics and composite materials strengthened by light
weight carbon and glass fibers are transforming the automobile and
aerospace industries
making plastics requires fossil fuels and oil
Substitution may not always be possible :
platinum, industrial catalyst
chromium : stainless steel
We Can Recycle and Reuse
Valuable Metals
Recycling
Lower environmental impact than mining and
processing virgin materials
Reuse - gold, silver, iron, copper, steel, aluminum,
platinum
Recycling aluminum beverage cans and scrap
aluminum produces 95% less air pollution, 97% less
water pollution and uses 95% less energy
There Are Many Ways to Use Mineral
Resources More Sustainability
How can we decrease our use and waste of mineral
resources?
Pollution and waste prevention programs
3M : Pollution Prevention Pays (3P)
Cleaner production : air pollution 70% lower, saved
$750 million in waste disposal and material costs
Sustainable Use of Nonrenewable
Minerals
Industrial Ecosystems: Copying
Nature
Mimic nature: recycle and reuse most minerals and
chemicals : waste outputs of one organism becomes the
nutrient inputs of another
Resource exchange webs : wastes of one
manufacturer becomes the raw materials for another
Ecoindustrial parks on brownfields, which are
abandoned industrial sites
Industrial forms of biomimicry
Benefits : come up with new environmentally beneficial and less
resource-intensive chemicals
Better image among consumers
An Industrial Ecosystem in
Denmark Mimics Natural Food Web