Urban Agriculture Lecture Notes PDF

Summary

This document is lecture notes on the topic of urban agriculture. It discusses the challenges of feeding a growing population, traditional agriculture, and sustainable agriculture practices. It also covers various factors that underpin agriculture, such as soil, water, and fertilizers.

Full Transcript

Chapter 7
Urban Agriculture
This lecture will help you understand:

Challenges of feeding a growing human population
Traditional, industrial, and sustainable agriculture
The Green Revolution
The importance of soil
Soil erosion and degradation
Irrigation, fertilizers, and pest management
Genetic engineering
Raising animals for food
Organic agriculture
The Race to Feed the World

Industrial agriculture has
boosted worldwide Figure 7.1 Global production of most foods has
production of food and fiber risen more quickly than the world population.

immensely, but has also
brought increased pollution
and resource depletion.
– Organic farming
decreases efficiency, but
also has far fewer
environmental impacts.
We face undernutrition, overnutrition, and
malnutrition (1 of 3)
Despite improved food production, 800 million people
suffer from undernutrition, receiving fewer calories than
the minimum dietary requirement.
Most people who are undernourished live in developing
countries, although 49 million people are classified as
“food insecure.”
– Food security is the guarantee of an adequate, safe,
nutritious, and reliable food supply.
We face undernutrition, overnutrition, and
malnutrition (2 of 3)
The number of people suffering Figure 7.2 The number and the
from food insecurity has percentage of people in the developing
world who suffer undernutrition have
decreased since the 1960s. each been declining.
Overnutrition, receiving too
many calories per day, has grown
in developing countries due to the
abundance of cheap junk food
and sedentary lifestyles.
– Excess weight leads to heart
disease, diabetes, stroke,
some forms of cancer, and
other health issues.
Malnutrition is a shortage of
specific nutrients, such as lipids,
proteins, vitamins, or minerals.
The Changing Face of Agriculture

Agriculture provides our most basic daily needs – from the
cotton in our clothes to the food on our plates.

Agriculture is also responsible for some of our biggest
impacts on the environment, making the development of
sustainable practices essential.
Several factors underpin agriculture

Agriculture is the practice of raising crops and livestock
for human use and consumption.
– Most of our food and fiber is obtained from cropland,
land used to raise crops for human use.
– Rangeland, or pasture, is land used for grazing
livestock.
Urban agriculture includes the cultivating, processing and
distributing agricultural products in urban and suburban
areas.
Growing crops and raising animals require inputs of
resources – soil, sunlight, water, nutrients, and pollinators.
Today, more than 1 out of every 3 acres of land on Earth is
used to produce food and fiber.
Industrial agriculture is a recent human invention (2 of 2)

In traditional agriculture, the work of cultivating,
harvesting, and distributing crops was performed by
human and animal muscle power.
– Most farmers planted polycultures, mixtures of
different crops in small plots of land.

Industrial agriculture introduced large-scale
mechanization and fossil fuel consumption into agriculture.
– Higher rates of irrigation, synthetic fertilizers, and
chemical pesticides
– Greater prevalence of monocultures, where farmers
grow vast areas of single crops in orderly rows
Sustainable agriculture reduces environmental
impacts
Sustainable agriculture maintains healthy soil, clean
water, pollinators, and other vital resources.
– Mimic the way natural ecosystems function.
– Low-input agriculture is an approach that uses less
amounts of fossil fuels, water, pesticides, fertilizers,
growth hormones, and antibiotics than are used in
industrial agriculture.
Requires an understanding of the soil, water, nutrients, and
pollinators that underpin agriculture.
Soils Figure 7.6 Mature soil consists of layers, or horizons,
that have different attributes.
Soil is a system consisting
of disintegrated rock,
organic matter, water,
gases, nutrients, and
microorganisms.
– Soil is derived from
rock, but shaped by
microorganisms.
– 50% mineral matter, 5%
organic matter, and
45% pore space.
Minerals dissolved or suspended in water can be transported
downward in a process called leaching.
Soil is renewable, but at a very slow rate (centuries, decades,
or millennia).
Watering and Fertilizing Crops

The artificial provision of water beyond Figure 7.8 Irrigation methods vary
in their water use.
what is received by precipitation is
irrigation.
– Irrigation is necessary with water-
intensive crops (like rice) and in areas
with dry climates.
– Irrigation is the largest use of water
by humans, making up 70% of all
fresh water withdrawn.
Waterlogging occurs when irrigation
oversaturates the soil to the point where
water drowns plant roots, depriving them
of gases.
Fertilizers boost crop yields but can be overapplied (1 of 2)

Fertilizers are substances that contain essential nutrients
for plant growth.
Inorganic fertilizers are mined or synthetically
manufactured.
Organic fertilizers are made of the remains or wastes
from organisms, including manure, crop residue, charcoal,
fresh vegetation, and compost.
– Compost is a mixture produced when decomposers
break down organic matter in a controlled environment.
Fertilizers boost crop yields but can be overapplied (2 of 2)

Since the Green Revolution, Figure 7.9 Use of synthetic, inorganic
fertilizers has risen sharply over the past
farmers have increasingly half-century.
relied on nutrients from
inorganic fertilizers.
– These nutrients are more
quickly leached, creating
other environmental
problems.
Sustainable fertilizer use involves monitoring and
targeting nutrients
Farmers who use drip irrigation can add fertilizer directly to
the water, thereby releasing it only at the plant roots.
Precision agriculture involves monitoring soil nutrient
levels and only applying specific types of fertilizer when
needed.
Organic fertilizer use is embraced, because it provides
additional benefits, such as improving soil structure,
nutrient retention, and water-retaining capacity.
Conserving Agricultural Resources

Soil degradation is the deterioration in quality and
productivity of soil.
Erosion is the removal of material from one place and its
transport to another by wind or water.
– When eroded material is left at a new location, it is
called deposition.
– Overcultivating fields or excessive tilling (plowing),
excessive grazing, and clearing forests on steep
slopes.
One study determined that U.S. croplands lose about
2.5 cm (1 in.) of topsoil every 15–30 years.
The Dust Bowl prompted the United States to fight
erosion
In the late 19th and early 20th centuries, farmers moving into the
Western Plains of the United States began plowing up native
grassland plants in favor of wheat.
A severe drought in the 1930s worsened the impacts, causing the
region’s strong winds to erode millions of tons of topsoil.
Figure 7.10 Drought and poor agricultural practices devastated millions of U.S. farmers in the 1930s in the Dust Bowl.
Policy can promote conservation measures in
agriculture (1 of 2)
Many nations spend billions in subsidies to promote
unsustainable practices, such as growing water-thirsty
crops in desert regions.
– In the United States, one-fifth of an average farmer’s
income comes from subsidies.
Subsidies help to stabilize and secure the income of
farmers, but they also lead to land being cultivated that
otherwise would not be.
– This artificially increases food production, lowering
prices for other farmers.
Policy can promote conservation measures in
agriculture (2 of 2)
Every 5–6 years, the U.S. Congress passes legislation
called the Farm Bill that guides agricultural policy.

The Conservation Reserve Program, first established in
the 1985 Farm Bill, pays farmers to convert damaged
cropland to conservation reserves.

In response to the Dust Bowl, the U.S. government passed
the Soil Conservation Act of 1935, which established an
agency (Natural Resources Conservation Service)that
worked with farmers to combat erosion.
Controlling Pests, Preserving Pollinators

A pest is any organism that damages crops or livestock.

A weed is any plant that competes with crops.

Industrial monocultures limit the ability of natural enemies
to control pest populations, causing farmers to turn to
chemical suppression.
We have developed thousands of chemical pesticides

Pesticides include synthetic chemicals that kill insects
(insecticides), plants (herbicides), and fungi (fungicides).
– Nearly 400 million kg of ingredients from pesticides are
applied in the United States each year.

Pesticides also kill nontarget organisms, including
predators and parasites of pests and pollinators.
Pests evolve resistance to pesticides (1 of 2)
Chemical pesticides tend to become less effective over time as
pests evolve resistance to them.
Most pests occur in huge numbers, so it is likely that a few have
genes that detoxify or metabolize a given pesticide.

Figure 7.12 Through the process of natural selection, crop pests often evolve resistance to the
poisons we apply to kill them.
 Pests evolve resistance to pesticides (2 of 2)
Individuals with the gene will survive and reproduce at greater
rates, creating a new generation with a much higher rate of
carrying the gene.
– Eventually the pesticide becomes ineffective and must be
replaced by a new one. This is called the “pesticide
treadmill.”

[Figure 7.12 Continued]
Biological control pits one organism against another

The most obvious alternative to chemical pesticides is
biological control or biocontrol, where natural predators
or parasites are introduced to eliminate the pest.
– Parasitoid wasps, for example, are natural enemies of
many caterpillars.
Integrated pest management combines biochemical
and chemical methods
Integrated pest management (IPM) combines biocontrol,
chemical pesticides, habitat alteration, crop rotation,
transgenic crops, alternative tillage methods, and
mechanical pest removal.
– This has been highly effective in Indonesia, which
increased rice production while cutting pesticide
subsidies and overall pesticide use.
Pollinators are beneficial “bugs” worth preserving (1 of 2)

Pollination is the process by which male plant sex cells
(pollen) fertilize female plant sex cells (ova, or egg cells).
– Grasses and conifer trees are pollinated by wind.
– Plants with bright flowers attract animals (pollinators),
which transfer pollen as they move from flower to
flower.
Pollinators are beneficial “bugs” worth preserving (2 of 2)

Today, many pollinating insects are dwindling in number
due to pesticide use and habitat loss.
Colony collapse disorder is a phenomenon where a
majority of worker bees in a hive disappear, endangering
the queen and developing larvae.
Restoring bee populations will require establishing more
wildflowers and flowering shrubs near farm fields and
highways and decreasing the use of chemical insecticides.
Raising Animals for Food
As global wealth and commerce have increased, so have
the production and consumption of meat, milk, eggs, and
other animal products.
– Meat production has grown more than fivefold since
1950, and per capita meat consumption has doubled.

Figure 7.13 Per-person production of meat
from farmed animals and of seafood has risen
steadily worldwide.
Our food choices are resource choices (1 of 3)

Every time that one organism consumes another, only
about 10% of the energy moves to the next trophic level.
– Feeding grain to a cow and eating beef from the cow
result in loss of most of the grain’s energy to the cow’s
metabolism.

Eating lower on the food chain (a more vegetarian diet) is
more energy-efficient and reduces our ecological footprint.
Our food choices are resource choices (2 of 3)

Some animals convert grain
feed into milk, meat, or eggs
more efficiently than others.

Figure 7.14 Producing different animal food products
requires different amounts of animal feed.
Our food choices are resource choices (3 of 3)
Based on these difference in energy conversion efficiencies, a footprint
of land area, water weight, and CO2 equilvants has been calculated for
producing 1 kg of edible protein for each animal.
– Animal agriculture accounts for 14.5% of our greenhouse gas
emissions—more than driving.

Figure 7.15 Producing different types of animal products requires different amounts of (a) land
and (b) water—and releases different amounts of (c) greenhouse gas emissions.
Feedlots have benefits and costs (1 of 2)

Feedlots are huge pens designed to provide high-energy
feed to animals living in high densities.
– These are also known as factory farms or confined
animal feeding operations (CAFOs).
Feedlots have the benefit of being more economically
efficient and reducing grazing impacts by the animals.
Feedlots have benefits and costs (2 of 2)

Feedlots can also produce more intensive pollution due to
the release of highly concentrated waste.
– Pollution is rich in nitrogen and phosphorous, so it
contributes to eutrophication.
– Feedlot waste contains bacterial and viral pathogens.
– Hormones, antibiotics, and other drugs administered to
animals may also be excreted.
We raise seafood with aquaculture (1 of 2)

Due to plummeting wild fish populations and increasing
demand for seafood, aquaculture, the cultivation of
aquatic organisms in controlled environments, may be the
answer.

Aquaculture increases food supplies and protein sources,
increasing overall food security.
– Pros: reduces overfishing of wild fish and the
unintended catch of other organisms called bycatch.
– Cons: antibiotic overuse, degradation of coastal
ecosystems, and spreading disease or invasive
species into nearby ecosystems.
We raise seafood with aquaculture (2 of 2)

The first genetically modified animal to become approved
for human consumption is a salmon that can grow faster
and reach larger sizes than wild salmon.

Figure 7.16 Transgenic salmon (top) grow faster
than wild salmon of the same species.
Genetically Modified Food (1 of 4)

Genetic engineering refers to any process where
scientists directly manipulate an organism’s genetic
material (DNA).
Genetically modified (GM) organisms (GMOs) contain
recombinant DNA, meaning it has been produced from
multiple organisms.
Genetically Modified Food (2 of 4)
An organism that contains DNA
from another species is called a
transgenic organism.
– The genes that move between
them are called transgenes.
Biotechnology creates products
derived from organisms.

Figure 7.17 To create recombinant DNA, scientists follow several steps.
Biotechnology is transforming the products around us
(1 of 2)

Sales of GM seeds have increased in the United States
and other countries.

Figure 7.18 GM crops have spread with remarkable speed since their commercial
introduction in 1996.
Biotechnology is transforming the products around us
(2 of 2)

Soybeans account for more than half of the GM crops grown worldwide.
The United States, Brazil, Argentina, India, and Canada accounted for
90% of production in 2017.

Figure 7.19 So far, genetic engineering has mainly involved common crops grown in
industrialized nations.
 The Growth of Sustainable Agriculture

One approach is organic agriculture, including practices
that do not include synthetic pesticides, fertilizers,
hormones, or antibiotics.
Figure 7.21 Organic agriculture is growing.
About 80% of Americans buy
organic food at least
occasionally, and most retail
groceries offer it.
The average food product
sold in a U.S. supermarket
travels at least 1600 km
(1000 mi) from the farm.
At farmers’ markets, consumers buy meats and produce from
local producers.
Urban Agriculture
Sustainable agriculture provides a roadmap for the
future
Sustainable agriculture must meet the triple bottom line of
social, economic, and environmental dimensions:
– Provide food security
– Be profitable to famers and ranchers
– Conserve resources for future agriculture
Let’s Start Our Plant Experiments

Today, we will prep for our 6-week plant experiments!