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6
Soils, agriculture, and the future of food
Key Words
A horizonagricultureaquacultureB horizonbedrockbiocontrolbiological controlbiotechnologyC horizonconservation tillage contour farmingconventional irrigationcrop rotationcroplandsdepositiondesertificationdrip irrigationDust BowlE horizon
erosionfeedlotsfertilizerfood securitygenetic engineeringgenetically modified (GM) organisms green revolutiongully erosionhorizonhumusindustrialized agricultureinorganic fertilizersintegrated pest management (IPM)irrigationleachinglow input agriculturemonocultureno-till agricultureO horizon
organic agricultureorganic fertilizersovergrazingparent materialpesticidespollinationprecautionary principleR horizonrangelandsrill erosionsalinizationseed bankssheet erosionshelterbeltssoilsoil profilesplash erosionstrip croppingsustainable agricultureterracingtopsoil
traditional agriculturetransgenicwaterloggedweathering
Objectives• Soil science fundamentals
• Soil erosion and degradation
• Soil conservation policies
• Pest management and pollination
• Genetically modified food and preserving crop diversity
• Feedlot agriculture and Aquaculture
• Organic agriculture
Central Case: No-Till Agriculture in Brazil
• Southern Brazil’s farmers were suffering falling yields, erosion, and pollution from agrichemicals.
• They turned to no-till farming, which bypasses plowing.
• Erosion was reduced, soils were enhanced, and yields rose greatly. No-till methods are spreading worldwide.
Agriculture today
We have converted 38% of Earth’s surface for agriculture, the practice of cultivating soil, producing crops, and raising livestock for human use and consumption.
Croplands (for growing plant crops) and rangelands (for grazing animal livestock) depend on healthy soil.
Croplands
• Help maintain water flow and soil infiltration
• Provide partial erosion protection • Can build soil organic matter
• Store atmospheric carbon
• Provide wildlife habitat for some species
Ecological Services Economic Services
• Food crops
• Fiber crops
• Crop genetic resources
• Jobs
Natural Capital
Croplands
Ecological Services
Economic Services
•Help maintain water flow and soil infiltration
•Provide partial erosion protection
•Can build soil organic matter
•Store atmospheric carbon
•Provide wildlife habitat for some species
•Food crops
•Fiber crops
•Crop genetic resources
•Jobs
Soil as a system
Parent material, such as bedrock, is weathered to begin process of soil formation.
Parent material = the base geological material in a location
Bedrock = the continuous mass of solid rock that makes up Earth’s crust
Weathering = processes that break down rocks
World soil conditions
Soils are becoming degraded in many regions.
Figure 8.1a
Soil degradation by continent
Europe’s land is most degraded because of its long history of intensive agriculture.
But Asia’s and Africa’s soils are fast becoming degraded.
Figure 8.1b
Causes of soil degradation
Most soil degradation is caused by:
• livestock overgrazing
• deforestation
• cropland agriculture.
Figure 8.2
Components of soil
Soil is a complex mixture of organic and inorganic components and living organisms.
Humus
Dark, crumbly mass of undifferentiated material made up of complex organic compounds
Soils with high humus content
hold moisture better and
are more productive for plant life.
Soil profile
Consists of layers called horizons.
Simplest:
A = topsoil
B = subsoil
C = parent material
But most have O, A, E, B, C, and R
Figure 8.8
Soil profileO Horizon: Organic or litter layer
A Horizon: Topsoil. Mostly inorganic minerals with some organic material and humus mixed in. Crucial for plant growth
E Horizon: Eluviation horizon; loss of minerals by leaching, a process whereby solid materials are dissolved and transported away
B Horizon: Subsoil. Zone of accumulation or deposition of leached minerals and organic acids from above
C Horizon: Slightly altered parent material
R Horizon: Bedrock
Soil characterization
Soil can be characterized by color and several other traits:Texture (percentage sand, silt, clay)StructurePorosityCation exchange capacity pHParent MaterialInfiltration rateNutrient concentrations
Best for plant growth is loam, an even mix of sand, silt and clay.
Erosion and deposition
Erosion = removal of material from one place and its transport elsewhere
by windor water
Deposition = arrival of eroded material at a new location
These processes are natural, and can build up fertile soil.
But where artificially sped up, they are a big problem for farming.
Erosion and Deposition
Sand dunes around Moses Lake are all that are left of the wind erosion in that area. The smaller particles, silt and clay were blown eastward toward the Palouse. The deposition of the silt and clay particles led to the formation of the Palouse Hills. The Palouse Hills are a wind/water erosional surface.
Erosion
Commonly caused by:
• Overcultivating, too much plowing, poor planning
• Overgrazing rangeland with livestock
• Deforestation, especially on slopes
Types of soil erosion
Figure 8.11
Splash erosion
Rill erosion
Gully erosion
Sheet erosion
Erosion: A global problem
Over 19 billion ha (47 billion acres) suffer from erosion or other soil degradation.
Mississippi River…to thin to plow to thick to drink (Sam Clemens)
DesertificationA loss of more than 10% productivity due to:
• Erosion
• Soil compaction
• Forest removal
• Overgrazing
• Drought
• Salinization
• Climate change
• Depletion of water resources
• etc.
When severe, there is expansion of desert areas, or creation of new ones, e.g., the Middle East, formerly, “Fertile Crescent”.
The Dust Bowl
Drought and degraded farmland produced the 1930s Dust Bowl.
Storms brought dust from the U.S. Great Plains all the way to New York and Washington, and wrecked many lives.
Figure 8.14
Colorado Kansas
DustBowl
Oklahoma
New Mexico
Texas
MEXICO
ConsequencesCauses
Worsening drought
Famine
Economic losses
Lower living standards
Environmentalrefugees
Overgrazing
Deforestation
Erosion
Salinization
Soil compaction
Natural climate change
Soil conservation
As a result of the Dust Bowl,
the U.S. Soil Conservation Act of 1935 and
the Soil Conservation Service (SCS) werecreated.
SCS: Local agents in conservation districts worked with farmers to disseminate scientific knowledge and help them conserve their soil.
Preventing soil degradation
Several farming strategies to prevent soil degradation:
• Crop rotation
• Contour farming
• Intercropping
• Terracing
• Shelterbelts
• Conservation tillage
Crop rotation
Alternating the crop planted (e.g., between corn and soybeans) can restore nutrients to soil and fight pests and disease.
Figure 8.16a
Contour farming
Planting along contour lines of slopes helps reduce erosion on hillsides.
Figure 8.16b
Intercropping
Mixing crops such as in strip cropping can provide nutrients and reduce erosion.
Figure 8.16c
(c) Alley cropping
Terracing
Cutting stairsteps or terraces is the only way to farm extremely steep hillsides without causing massive erosion. It is labor-intensive to create, but has been a mainstay for centuries in the Himalayas and the Andes.
Figure 8.16d
Shelterbelts
Rows of fast-growing trees around crop plantings provide windbreaks, reducing erosion by wind.
Figure 8.16e
Conservation tillage
No-till and reduced-tillage farming leaves old crop residue on the ground instead of plowing it into soil. This covers the soil, keeping it in place. Here, corn grows up out of a “cover crop.”
Figure 8.16f
Conservation tillage
Conservation tillage is not a panacea for all crops everywhere.
It often requires more chemical herbicides (because weeds are not plowed under).
It often requires more fertilizer (because other plants compete with crops for nutrients).
But legume cover crops can keep weeds at bay while nourishing soil, and green manures can be used as organic fertilizers.
Reduces erosion
Saves fuel
Cuts costs
Holds more soil water
Reduces soil compaction
Allows several crops per season
Does not reduce crop yields
Reduces CO2
release from soil
Can increase herbicide use for some crops
Leaves stalks that can harbor crop pests and fungal diseases and increase pesticide use
Requires investment in expensive equipment
DisadvantagesAdvantages
Trade-Offs
Conservation Tillage
Irrigation
The artificial provision of water to support agriculture
70% of all freshwater used by humans is used for irrigation.
Irrigated land globally covers more area than all of Mexico and Central America combined.
Irrigation has boosted productivity in many places… but too much can cause problems.
Waterlogging and salinization
Overirrigation can raise the water table high enough to suffocate plant roots with waterlogging.
Salinization (buildup of salts in surface soil layers) is a more widespread problem.
Evaporation in arid areas draws water up through the soil, bringing salts with it. Irrigation causes repeated evaporation, bringing more salts up.
Improved irrigation
In conventional irrigation, only 40% of the water reaches plants.
Efficient drip irrigation targeted to plants conserves water, saves money, and reduces problems like salinization.
Figure 8.17
Reduce irrigation
Switch to salt-tolerant crops(such as barley, cotton, sugar beet)
Prevention
Flushing soil(expensive andwastes water)
Not growing crops for 2-5 years
Installing under- ground drainagesystems (expensive)
Cleanup
Solutions
Soil Salinization
Fertilizers
Supply nutrients to crops
Inorganic fertilizers = mined or synthetically manufactured mineral supplements
Organic fertilizers = animal manure, crop residues, compost, etc.
Figure 8.18
Global fertilizer usages
Fertilizer use has risen dramatically in the past 50 years.
Figure 8.19b
Trade-Offs
Inorganic Commercial Fertilizers
Advantages Disadvantages
Do not add humus to soil
Reduce organic matter in soil
Reduce ability of soil to hold water
Lower oxygen content of soil
Require large amounts ofenergy to produce,transport, and apply
Release the greenhouse gas nitrous oxide (N2O)
Runoff can overfertilizenearby lakes and kill fish
Easy to transport
Easy to store
Easy to apply
Inexpensive to produce
Help feed one of every three people in theworld
Without commercialinorganic fertilizers,world food output coulddrop by 40%
Overgrazing
When livestock eat too much plant cover on rangelands, impeding plant regrowth
The contrast between ungrazed and overgrazed land on either side of a fenceline can be striking.
Figure 8.22
Overgrazing
Overgrazing can set in motion a series of positive feedback loops.
Figure 8.21
Recent soil conservation laws
The U.S. has continued to pass soil conservation legislation in recent years:
• Food Security Act of 1985
• Conservation Reserve Program, 1985
• Freedom to Farm Act, 1996
• Low-Input Sustainable Agriculture Program, 1998
Internationally, there is the UN’s “FAR” program in Asia.
Global food production
World agricultural production has risen faster than human population.
Figure 9.1
Global food security
However, the world still has 800 million hungry people, largely due to inadequate distribution.
And considering soil degradation, can we count on food production continuing to rise?
Global food security is a goal of scientists and policymakers worldwide.
Nutrition
Undernourishment = too few calories(especially developing world)
Overnutrition = too many calories(especially developed world)
Malnutrition = lack of nutritional requirements(causes numerous diseases, esp. in developing world)
Figure 9.2
The green revolution
An intensification of industrialization of agriculture, which has produced large yield increases since 1950
Increased yield per unit of land farmed
Begun in U.S. and other developed nations; exported to developing nations like India and those in Africa
are more productive for plant life.
Transgenic contamination?
UC Berkeley researchers Ignacio Chapela (L) and David Quist (R) ignited controversy by claiming contamination of Mexican maize.
They later admitted some flaws in their methods, but debate continued, revealing the personal and political pressures of high-stakes scientific research.
From The Science behind the Stories
Monocultures
Intensified agriculture meant monocultures, vast spreads of a single crop.
This is economically efficient, but increases risk of catastrophic failure (“all eggs in one basket”).
Figure 9.4aWheat monoculture in Washington
Crop diversity
Monocultures also have reduced crop diversity.
90% of all human food now comes from only 15 crop species and 8 livestock species.
Biodiversity Loss
Loss and degradation of habitat fromclearing grasslands and forests anddraining wetland
Fish kills from pesticide runoff
Killing of wild predators to protectlivestock
Loss of genetic diversity fromreplacing thousands of wild cropstrains with a few monoculture strains
Soil
Erosion
Loss of fertility
Salinization
Waterlogging
Desertification
Air Pollution
Greenhouse gas emissions from fossilFuel issue
Other air pollutants from fossil fuel use
Pollution from pesticide sprays
WaterWater waste
Aquifer depletion
Increased runoff andflooding from land clearedto grow crops
Sediment pollution fromerosion
Fish kills from pesticiderunoff
Surface and groundwaterpollution from pesticidesand fertilizers
Overfertilization of lakesand slow-moving riversfrom runoff of nitrates and phosphates fromfertilizers, livestockwastes, and foodprocessing wastes
Human Health
Nitrates in drinking water
Pesticide residues in drinking water,food, and air
Contamination of drinking andswimming water with disease organisms from livestock wastes
Bacterial contamination of meat
The green revolution
Techniques to increase crop output per unit area of cultivated land (since world was running out of arable land)
Technology transfer to developed world in 1940s-80s: Norman Borlaug began in Mexico, then India.
Special crop breeds (drought-tolerant, salt-tolerant, etc.) are a key component.
It enabled food production to keep pace with population.
Green revolution: Environmental impacts
Intensification of agriculture causes environmental harm:
• Pollution from synthetic fertilizers
• Pollution from synthetic pesticides
• Water depleted for irrigation
• Fossil fuels used for heavy equipment
However, without the green revolution, much more land would have been converted for agriculture, destroying forests, wetlands, and other ecosystems.
2,000
1,500
1,000
500
0
Gra
in p
rod
uct
ion
(mill
ion
s o
f to
ns)
1950 1960 1970 1980 1990 2000 2010
Total World Grain Production
Year
Feeding the world
In 1983, the amount of grain produced per capita leveled off and began to decline.
Figure 8.3
Pest management
Terms pest and weed have no scientific or objective definitions.
Any organism that does something we humans don’t like gets called a pest or a weed.
The organisms are simply trying to survive and reproduce… and a monoculture is an irresistible smorgasbord of food for them.
Chemical pesticides
Synthetic poisons that target organisms judged to be pests
Pesticide use
Pesticide use is still rising sharply across the world, although growth has slowed in the U.S.
1 billion kg (2 billion lbs.) of pesticides are applied each year in the U.S.
Figure 9.5
Pests evolve resistance to pesticides
Pesticides gradually become less effective, because pests evolve resistance to them.
Those few pests that survive pesticide applications because they happen to be genetically immune will be the ones that reproduce and pass on their genes to the next generation.
This is evolution by natural selection, and it threatens our very food supply.
Pests evolve resistance to pesticides
1. Pests attack crop
2. Pesticide applied
Figure 9.6
Pests evolve resistance to pesticides
3. All pests except a few with innate resistance are killed
4. Survivors breed and produce pesticide-resistant population
Figure 9.6
Pests evolve resistance to pesticides
5. Pesticide applied again
6. Has little effect. More-toxic chemicals must be developed.
Figure 9.6
Biological control
Synthetic chemicals can pollute and be health hazards.
Biological control (biocontrol) avoids this.
Biocontol entails battling pests and weeds with other organisms that are natural enemies of those pests and weeds.
(“The enemy of my enemy is my friend.”)
Biological control
Biocontrol has had success stories.
Bacillus thuringiensis (Bt) = soil bacterium that kills many insects. In many cases, seemingly safe and effective.
Figure 9.7
Cactus moth, Cactoblastis cactorum (above), was used to wipe out invasive prickly pear cactus in Australia.
But biocontrol is risky
Most biocontrol agents are introduced from elsewhere.
Some may turn invasive and become pests themselves!
Cactus moths brought to the Caribbean jumped to Florida, are eating native cacti, and spreading.
Wasps and flies brought to Hawaii to control crop pests are parasitizing native caterpillars in wilderness areas.
Integrated pest management (IPM)
Combines biocontrol, chemical, and other methods May involve:
• Biocontrol
• Pesticides
• Close population monitoring
• Habitat modification
• Crop rotation
• Transgenic crops
• Alternative tillage
• Mechanical pest removal
Pollination
Process of plant reproduction: male pollen meets female sex cells
In many plants, animals transfer pollen to pollinate female plants, in mutualistic interaction to obtain nectar or pollen.
Figure 9.9
Honeybee pollinating apple blossom
Genetic modification of food
Manipulating and engineering genetic material in the lab may represent the best hope for increasing agricultural production further without destroying more natural lands.
But many people remain uneasy about genetically engineering crop plants and other organisms.
Genetic engineering uses recombinant DNA
Genetic engineering (GE) = directly manipulating an organism’s genetic material in the lab by adding, deleting, or changing segments of its DNA
Genetically modified (GM) organisms = genetically engineered using recombinant DNA technology
Recombinant DNA = DNA patched together from DNA of multiple organisms (e.g., adding disease-resistance genes from one plant to the genes of another)
Transgenes and biotechnology
Genes moved between organisms are transgenes, and the organisms are transgenic.
These efforts are one type of biotechnology, the material application of biological science to create products derived from organisms.
Genetic engineering vs. traditional breeding
They are similar:
We have been altering crop genes (by artificial selection) for thousands of years.
There is no fundamental difference: both approaches modify organisms genetically.
They are different:
GE can mix genes of very different species.
GE is in vitro lab work, not with whole organisms.
GE uses novel gene combinations that didn’t come together on their own.
Some GM foods
Figure 9.12
Golden rice: Enriched with vitamin A.But too much hype?
Bt crops: Widely used on U.S. crops.But ecological concerns?
Ice-minus strawberries: Frost-resistant bacteria sprayed on.Images alarmed public.
FlavrSavr tomato: Better taste?But pulled from market.
Some GM foods
Figure 9.12
Bt sunflowers: Insect resistant.But could hybridize with wild relatives to create “superweeds”?
Terminator seeds: Plants kill their own seeds. Farmers forced to buy seeds each year.
Roundup-Ready crops: Resistant to Monsanto’s herbicide. But encourages more herbicide use?
StarLink corn: Bt corn variety.Genes spread to non-GM corn; pulled from market.
Transferring Genes Into Plants
Click to view animation
.
Transferring genes into plants.
Prevalence of GM foods
Although many early GM crops ran into bad publicity or other problems, biotechnology is already transforming the U.S. food supply.
Two-thirds of U.S. soybeans, corn, and cotton are now genetically modified strains.
Prevalence of GM foods
Nearly 6 million farmers in 16 nations plant GM crops.
But most are grown by 4 nations.
The U.S. grows 66% of the world’s GM crops.
number of plantings have grown >10%/year
Figure 9.13
Scientific concerns about GM organisms
Are there health risks for people?
Can transgenes escape into wild plants, pollute ecosystems, harm organisms?
Can pests evolve resistance to GM crops just as they can to pesticides?
Can transgenes jump from crops to weeds and make them into “superweeds”?
Can transgenes get into traditional native crop races and ruin their integrity?
Scientific concerns about GM organisms
These questions are not fully answered yet.
In the meantime…
Should we not worry, because so many U.S. crops are already GM and little drastic harm is apparent?
Or should we adopt the precautionary principle, the idea that one should take no new action until its ramifications are understood?
Socioeconomic and political concerns about GM products
Should scientists and corporations be “tinkering with” our food supply?
Are biotech corporations testing their products adequately, and is outside oversight adequate?
Should large multinational corporations exercise power over global agriculture and small farmers?
Europe vs. America
Europe: has followed precautionary principle in approach to GM foods. Governments have listened to popular opposition among their citizens.
U.S.: GM foods were introduced and accepted with relatively little public debate.
Relations over agricultural trade have been uneasy, and it remains to be seen whether Europe will accept more GM foods from the U.S.
ProjectedDisadvantages
Need less fertilizer
Need less water
More resistant to insects,plant disease, frost, anddrought
Faster growth
Can grow in slightly saltysoils
Less spoilage
Better flavor
Less use of conventionalpesticides
Tolerate higher levels ofpesticide use
Higher yields
ProjectedAdvantages
Trade-OffsGenetically Modified Food and Crops
Irreversible andunpredictable genetic and ecological effects
Harmful toxins in foodFrom possible plant cellMutations
New allergens in food
Lower nutrition
Increased evolution ofPesticide-resistantInsects and plant disease
Creation of herbicide-Resistant weeds
Harm beneficial insects
Lower genetic diversity
Viewpoints: Genetically modified foods
Indra Vasil
Ignacio Chapela
“We should expect fundamental alterations in ecosystems with the release of transgenic crops… We are experiencing a global experiment without controls.”
“Biotech crops are already helping to conserve valuable natural resources, reduce the use of harmful agro-chemicals, produce more nutritious foods, and promote economic development.”
From Viewpoints
Preserving crop diversity
Native cultivars of crops are important to preserve, in case we need their genes to overcome future pests or pathogens.
Diversity of cultivars has been rapidly disappearing from all crops throughout the world.
Seed banks preserve seeds, crop varieties
Seed banks are living museums of crop diversity, saving collections of seeds and growing them into plants every few years to renew the collection.
Careful hand pollination helps ensure plants of one type do not interbreed with plants of another.
Figure 9.14
Animal agriculture: Livestock and poultry
Consumption of meat has risen faster than population over the past several decades.
Figure 9.15
Feedlot agriculture
Increased meat consumption has led to animals being raised in feedlots (factory farms), huge pens that deliver energy-rich food to animals housed at extremely high densities.
Figure 9.16
Feedlot agriculture: Environmental impacts
Immense amount of waste produced, polluting air and water nearby
Intense usage of chemicals (antibiotics, steroids, hormones), some of which persist in environment
However, if all these animals were grazing on rangeland, how much more natural land would be converted for agriculture?
Food choices = energy choices
Energy is lost at each trophic level.
When we eat meat from a cow fed on grain, most of the grain’s energy has already been spent on the cow’s metabolism.
Eating meat is therefore very energy inefficient.
Grain feed input for animal output
Some animal food products can be produced with less input of grain feed than others.
Figure 9.17
Land and water input for animal output
Some animal food products can be produced with less input of land and water than others.
Figure 9.18
Aquaculture
The raising of aquatic organisms for food in controlled environments
Provides 1/3 of world’s fish for consumption
220 species being farmed
The fastest growing type of food production
Aquaculture
Fish make up half of aquacultural production. Molluscs and plants each make up nearly 1/4.
Global aquaculture has been doubling about every 7 years.
Figure 9.19
Benefits of aquaculture
Provides reliable protein source for people, increases food security
Can be small-scale, local, and sustainable
Reduces fishing pressure on wild stocks, and eliminates bycatch
Uses fewer fossil fuels than fishing
Can be very energy efficient
Environmental impacts of aquaculture
Density of animals leads to disease, antibiotic use, risks to food security.
It can generate large amounts of waste.
Often animals are fed grain, which is not energy efficient.
Sometimes animals are fed fish meal from wild-caught fish.
Farmed animals may escape into the wild and interbreed with, compete with, or spread disease to wild animals.
Environmental impacts of aquaculture
Transgenic salmon (top) can compete with or spread disease to wild salmon (bottom) when they escape from fish farms.
Figure 9.20
Highly efficient
High yield in smallvolume of water
Increased yieldsthrough cross-breeding and genetic engineering
Can reduce over-harvesting of conventional fisheries
Little use of fuel
Profit not tied to price of oil
High profits
Advantages
Large inputs of land, feed, And water needed
Produces large and concentrated outputs of waste
Destroys mangrove forests
Increased grain productionneeded to feed some species
Fish can be killed by pesticide runoff from nearby cropland
Dense populations vulnerable to disease
Tanks too contaminated touse after about 5 years
Disadvantages
Trade-Offs
Aquaculture
• Reduce use of fishmeal as a feed to reduce depletion of other fish
• Improve pollution management of aquaculture wastes
• Reduce escape of aquaculture species into the wild
• Restrict location of fish farms to reduce loss of mangrove forests and other threatened areas
• Farm some aquaculture species (such as salmon and cobia) in deeply submerged cages to protect them from wave action and predators and allow dilution of wastes into the ocean
• Set up a system for certifying sustainable forms of aquaculture
Solutions
More Sustainable Aquaculture
Sustainable agriculture
Agriculture that can practiced the same way far into the future
Does not deplete soils faster than they form
Does not reduce healthy soil, clean water, and genetic diversity essential for long-term crop andlivestock production
Low-input agriculture = small amounts of pesticides, fertilizers, water, growth hormones, fossil fuel energy, etc.
Organic agriculture = no synthetic chemicals used. Instead, biocontrol, composting, etc.
Organic farming
Small percent of market, but is growing fast
1% of U.S. market, but growing 20%/yr
3–5% of European market, but growing 30%/yr
Organic produce:Advantages for consumers: healthier; environmentally better
Disadvantages for consumers: less uniform and appealing-looking; more expensive
Conclusions: Challenges
Chemical pesticides pollute, and kill pollinators, and pests evolve resistance.
GM crops show promise for social and environmental benefits, but questions linger about their impacts.
Much of the world’s crop diversity has vanished.
Feedlot agriculture and aquaculture pose benefits and harm for the environment and human health.
Conclusions: Challenges
Organic farming remains a small portion of agriculture.
Human population continues to grow, requiring more food production.
Soil erosion is a problem worldwide.
Salinization, waterlogging, and other soil degradation problems are leading to desertification.
Grazing and logging, as well as cropland agriculture, contribute to soil degradation.
Conclusions: Solutions
Biocontrol and IPM offer alternatives to pesticides.
Further research and experience with GM crops may eventually resolve questions about impacts, and allow us to maximize benefits while minimizing harm.
More funding for seed banks can rebuild crop diversity.
Ways are being developed to make feedlot agriculture and aquaculture safer and cleaner.
Conclusions: SolutionsOrganic farming is popular and growing fast.
Green revolution advances have kept up with food demand so far. Improved distribution and slowed population growth would help further.
Farming strategies like no-till farming, contour farming, terracing, etc., help control erosion.
Government laws, and government extension agents working with farmers, have helped improve farming practices and control soil degradation.
Better grazing and logging practices exist that have far less impact on soils.
High-yield polyculture
Organic fertilizers
Biological pest control
Integrated pestmanagement
Irrigation efficiency
Perennial crops
Crop rotation
Use of more water-efficient crops
Soil conservation
Subsidies for more sustainable farming and fishing
Increase
Soil erosion
Soil salinization
Aquifer depletion
Overgrazing
Overfishing
Loss of biodiversity
Loss of primecropland
Food waste
Subsidies for unsustainable farming and fishing
Population growth
Poverty
Decrease
Solutions
Sustainable Agriculture
•Waste les food
•Reduce or eliminate meat consumption
•Feed pets balanced grain foods instead of meat
•Use organic farming to grow some of your food
•Buy organic food
•Compost your food wastes
What Can You Do?
Sustainable Agriculture
QUESTION: Review
Integrated pest management may involve all of the following EXCEPT… ?
a. Close population monitoring
b. Biocontrol
c. Exclusive reliance on pesticides
d. Habitat modification
e. Transgenic crops
QUESTION: Review
What do seed banks do?
a. Lend money to farmers to buy seeds
b. Pay farmers to store seeds
c. Buy seeds from farmers
d. Store seeds to maintain genetic diversity
e. None of the above
QUESTION: Review
Which is NOT a benefit of aquaculture?
a. Provides a reliable protein source
b. Reduces pressure on natural fisheries
c. Produces no waste
d. Uses fewer fossil fuels than commercial fishing
e. All of the above are benefits
QUESTION: Weighing the Issues
Can we call the green revolution a success?
a. A huge success; it has saved millions from starvation because it increased food production to keep pace with population growth.
b. Not a success; its environmental impacts have outweighed its claimed benefits.
c. A success; its environmental impacts are balanced by the fact that it saved huge areas from deforestation.
QUESTION: Interpreting Graphs and Data
With 500 kg of water, you could produce … ?
a. 2 kg of protein from milk
b. Protein from 50 chickens
c. 750 kg of protein from beef
d. 15 eggs
Figure 9.18b
QUESTION: Viewpoints
Should we encourage the continued development of GM foods?
a. Yes; they will bring many health, social, and environmental benefits.
b. No, we should adopt the precautionary principle, and not introduce novel things until we know they are safe.
c. Yes, but we should proceed cautiously, and consider each new crop separately.
QUESTION: Review
Which statement is NOT correct?
a. Soil consists of disintegrated rock, organic matter, nutrients, and microorganisms.
b. Healthy soil is vital for agriculture.
c. Soil is somewhat renewable.
d. Soil is lifeless dirt.
e. Much of the world’s soil has been degraded.
QUESTION: Review
The A horizon in a soil profile… ?
a. Is often called the “zone of accumulation.”
b. Is often called “topsoil.”
c. Contains mostly organic matter.
d. Is the lowest horizon, deepest underground.
QUESTION: Review
Erosion occurs through… ?
a. Deforestation.
b. Excessive plowing.
c. Overgrazing rangelands.
d. Two of the above.
e. All of the above.
QUESTION: Review
Drip irrigation differs from conventional irrigation in that … ?
a. It is much less efficient.
b. It can cause salinization.
c. Water is precisely targeted to plants.
d. About 40% is wasted.
QUESTION: Weighing the Issues
You are farming an extremely steep slope that is sunny and very windy. What strategies would you consider using?
a. Crop rotation
b. Contour farming
c. Intercropping
d. Terracing
e. Shelterbelts
f. No-till farming
QUESTION: Interpreting Graphs and Data
Grain produced per person has… ?
a. Risen steadily
b. Fallen sharply
c. Increased since 1983
d. Decreased since 1983
Figure 8.3