Genetically Modified Crops Presentation PDF

Summary

This presentation discusses genetically modified crops, exploring their development, benefits, and drawbacks. It examines the global area of GM plantings and the impact on carbon emissions. The presentation also touches on various types of grains and their uses.

Full Transcript

 Genetically
Modified
Genetically Crops
modified (GM) crops: crops that have had their
genetic material (DNA) changed in a way that does not occur
naturally.

GM crops were initially developed in response to growing concern
about protecting crops from insects, unusual weather
patterns, and harmful pesticides.

Using genetic engineering and biotechnology, genes are
transferred from one organism to another to introduce new
or enhanced characteristics (traits).
These biologically robust plants have better durability or
nutritional value and their traits include:
Pesticide (such as herbicide and insecticide) tolerance
 Genetically
Modified Crops
The main GM crops grown commercially are herbicide and
insecticide-resistant corn, soybeans, cotton, and canola.

Other transgenic crops include:
Sweet potato resistant to a virus that could destroy most of the
African harvest
Rice with increased iron and vitamins that may alleviate
chronic malnutrition in Asian countries
Vegetables with higher vitamin E content to help fight heart
disease (antioxidant)
Bananas that produce human vaccines against infectious
diseases such as hepatitis B
A variety of plants that are able to survive weather
extremes https://www.youtube.com/watch?
v=_FZewFiw7IE
 Genetically
Modified Crops
GM crops are becoming more and more mainstream.

However, there is divided public opinion about the health and
environmental impacts of producing and consuming crops
produced in a lab.

Advantages:
Genetic modification has the potential to develop crops that are
resistant to a number of harmful factors like drought, disease,
insects, chemicals, and other forms of stress.
In turn, this reduces global hunger and improves food
security by increasing crop availability.
It also improves the economy by increasing crop yields.
Genetic modification also has the potential to infuse existing crops
with essential vitamins and minerals.
 Genetically
Modified Crops
Disadvantages:
There is so little known about the effects of GM crops on
human health and the environment that their potential long-
term risks may outweigh their short-term benefits.

Arguments against GM crops state that: it can adversely harm
human health in the form of allergic reactions and transferal
of antibiotic-resistant genes from GM foods to the human
body.

Environmental impacts of GM crops can encompass issues such as:
 Possible loss of other conventional plants, ability of a GM
organism to introduce engineered genes to native fauna
 Increase in the use of chemicals in agriculture (because
many are resistant to pesticides) development of herbicide
 Global Area of
GM Crops
GM crops were first commercialized in the early 1990s.

The global plantation area of GM crops has been growing for
more than two decades. It reached in 2020, 186 million
hectares.

 North America and South America accounted for 87% of the
global GM crop area in 2014 (with 84.7 million and 73.3 million
hectares, respectively).

 They were followed by Asia (19.5 million hectares), Africa (3.3
million hectares), Oceania (0.5 million hectares), and Europe
(0.1 million hectares).
Today, more than 17 million farmers are planting GM
crops in 30 countries
 he United
States had the
largest area of
genetically
modified crops
worldwide in
2019, at 71.5
million
hectares,
followed by
Brazil with a
little over 52.8
million
hectares.
Million hectares
Statista
 Global Area of GM
Crops
Global Area of GM Crops by
Continent (1996-2014)

ISAAA, Worldwatch
 Growth of GM
Crops
In 1998, there was a rapid expansion of GM crops in the U.S.
and Argentina.

In the first decade of the 21st century, active growth in planted
area expanded from North and South America to Asia and
Africa.

Then, developing countries in South America (mainly Brazil
and Argentina), Asia (mainly China and India), and Africa
(mainly South Africa) added a larger area than the industrial
countries did.

Since 2012, the developing world has been planting larger
areas of GM crops than developed countries.
 Growth of GM Crops

Annual Added Plantation Area and
Growth Rates of GM Crops
(1998-2014)

ISAAA, Worldwatch
 Countries Growing
GM Crops
The largest 5 producers alone planted 89.7% of all GM crop areas on
the planet.

Interestingly, 6 of the 15 largest producers—are developing
countries—started officially planting GM crops only within the
last decade.

 For example, Brazil did not officially approve the planting of GM crops
until 2003.
 However, Brazil is second place worldwide.
 Brazil’s GM crop now mainly consists of herbicide-tolerant soybeans.
Countries Growing GM
Area Planted inCrops
GM Crops, by Country and
Share of Global Total,
2014

ISAAA, Worldwatch
 Commercially Grown
GM Crops
In 2017, the most widely grown GM crops were:
 Soybeans (90.7 million hectares)
 Maize (55.2 million hectares)
 Cotton (25.1 million hectares)
 Canola (9 million hectares)

Total land area around the world planted different genetically modified (GM) crops (2017)

Other commercially planted GM crops include: Sugar beet,
alfalfa, papaya, potato, squash, tomato, sweet pepper, and
eggplant

Insect-resistant poplar trees have been commercially
planted in China.
 Commercially Grown
GM Crops
95% of canola in Canada, 99% of cotton in Australia, 95% of
cotton in India, 99% of cotton in Argentina, over 95% of
soybean in Paraguay, and 100% of soybean in Argentina are
already genetically modified.

Herbicide tolerance has been the dominant trait
among all officially approved GM crops since 1996,
accounting for nearly 60% of all GM crops.

Other introduced traits include virus resistance,
drought tolerance, nutrient enhancement, and
market value enhancement.
 Driving Forces of GM
Crop Growth
Financial: In 2016, the direct global farm income benefit
from GM crops was $18.2 billion, equal to an average
increase in income of $102/hectare.

Hunger and poverty: GM crops could help alleviate
hunger and poverty, but the real effect deserves
closer assessment.

 Instead of producing more food by improving yield—the
benefit of these technologies consists of saving time and
effort in farming, as well as reduced market risks for
farmers.

 GM technology adoption has increased farmer profits
 Driving Forces of GM
Crop Growth
Animal feed and oil production: the high demand for animal
feed (soybean and maize) and oil (canola and soybean) not just for
food.

 However, this raises at least two noteworthy concerns:
First, from a social perspective, although the efficiency
improvement may give farmers time to turn to other
sources of income, it has led to loss of land and livelihoods
when farmers with more assets expand to take over the
land of less resourceful and less protected small farmers.

Second, from an environmental perspective, the high
demand on GM crops is affecting the biodiversity of fauna
and flora.
Genetically Modified (GM) Crop Use
1996-2020: Impacts on Carbon Emissions
Graham Brookes (2022) Genetically Modified (GM) Crop Use 1996–2020:
Impacts on Carbon Emissions, GM Crops & Food, 13:1, 242-261, DOI:
10.1080/21645698.2022.2118495
https://doi.org/10.1080/21645698.2022.2118495
 The use of GM crops has impacted GHG
emissions at a global level

Over the 24 year period examined to 2020, the
widespread use of GM insect-resistant & herbicide-
tolerant seed technology has led to cuts in on-farm
fuel use.

This has led to a significant reduction in the
release of GHGs from the GM cropping area.

In 2020, this was equal to saving 23,631 million kg of
CO2, which is equivalent to taking 15.6 million cars off
the road for a year (~ 49% of the registered cars in
the UK)!
 The 3 main GHGs of relevance to agriculture are
carbon dioxide, nitrous oxide & methane

GM crops contribute to lowering levels of GHGs from 3
principle sources:
1- Reduced fuel use from fewer herbicide or
insecticide applications

2- The use of “no till” & “reduced till” farming
systems

3- Intensification of crop production resulting in higher
crop yields
 Grain
Production

Romy Chammas M.Sc.
Fall 2024
 Grains
Grains are commonly referred to as ‘cereals’, and they are
edible seeds.

There are many types of grains:
 Wheat, oats, rice, corn (maize), barley, sorghum, rye, and
millet
 Within these groups, there are also varieties; for example:
couscous, burghul, freekeh, emmer, and spelt are all types
 Grains
A wholegrain is a grain that contains all the essential
parts: the endosperm, germ, and bran and the
naturally-occurring nutrients of the entire grain

This is in contrast to refined/processed grains, which
retain only the endosperm.
Grains
Grains
 Wheat
Wheat is the most widely cultivated cereal crop in the
world.

Wheat has become a favorite grain because of the
diversity it provides in culinary applications.

Flour is most commonly made from wheat, but can also be
made from corn, rice, rye, and barley.

Flour is then used to make a wide range of foods, including
bread, pasta, muffins, noodles, biscuits, cakes,
pastries, and sauces.
 Oats
Unique among grains, oats almost never have their bran
and germ removed in processing, so most food containing
oats as an ingredient are considered wholegrains.

Oats are naturally rich in beta-glucan, which is a soluble fiber.

Beta-glucan has been shown to improve blood glucose control
after a meal, improve insulin responses, and decrease
cholesterol levels.

Oats also have a unique antioxidant, Avenanthramide, that
helps protect
blood vessels from the damaging effects of LDL
cholesterol.

For consumption, oats are most commonly rolled/crushed into
 Rice
Rice is one of the most eaten grains in the world. It is grown in
over 100 countries.

Rice is the staple food of 3 of the most populated regions of
the world: China, India, and Indonesia.

More than 100 varieties of rice are grown worldwide.

White rice, basmati rice, brown rice, arborio rice (Italian), black
rice, sushi rice etc…

To produce white rice, the nutrient-rich bran layer is removed.

Besides being eaten alone, rice is used to make rice flour (used to
make rice noodles and crackers), rice bran (used as a healthy
ingredient in some baked products like bread), and sake (Japanese
 Corn

In its immature form, corn is the familiar yellow corn on the
cob.

When it matures and dries out, it is used like other
grains to make grain foods like breakfast cereal and
tortillas.

Corn is one of the world’s most important crops because
it is used widely in food manufacturing.

Besides being eaten on its own, corn is used to make corn
starch, corn flour, breakfast cereals (cornflakes), corn
OECD-FAO AGRICULTURAL OUTLOOK 2023-
2032 © OECD/FAO 2023

Chapter 3 - Cereals
 Grain
Production
World Grain Production
(1961-2012)

FAO, Worldwatch
 Production
Over the next 10 years, the growth of cereal demand is expected
to be slower than the past decade due to weaker growth in
feed demand, biofuels, and other industrial uses.

Moreover, in many countries direct human per capita food
consumption of most cereals is approaching saturation levels.

Most of the increase in food demand is linked to population
growth, particularly in low and lower middle-income
countries.

In the next decade, global cereal production growth will be
due to higher yields and more intensive use of existing
arable land.

The expected increase is attributed to the wider availability
and adoption of new and improved seed varieties, more
intense and efficient use of inputs, and improved
agricultural practices.
 Production
Global production of cereals is projected to
increase from its current level by about 320 Mt to
3.1 Bln T by 2032, largely from maize and rice.

As over the past decade, the increase is expected to
originate primarily in Asian countries, which will
account for about 45% of global growth.

Overall, 17% of global cereal production was traded
internationally in 2022.

However, this share varies across the different
cereals ranging from 10% for rice to 25% for wheat.
This ratio is expected to remain stable over the next
decade
 Production
It is projected that world cereal trade will increase by 11%,
totaling 530 Mt by 2032:

Wheat will contribute to 43% of this growth,
Maize: 34%
Rice: 20%
Other coarse grains: 3%

The Russian Federation (hereafter “Russia”) is projected
to remain the largest wheat exporter, supplying 23% of
global exports in 2032.

The United States will remain the leading exporter of
maize closely followed by Brazil, while the European
Union will remain the main exporter of other coarse
grains.
Production
Consumption
Grain crops are mainly used for:
Human consumption
Animal feed
Biofuels

Asian countries will lead demand growth of cereals for food and feed.

Cereal demand will continue to be dominated by food use, closely followed
by animal feed use.

In 2032, 41% of all cereals will be directly consumed by humans, while 37% will
be used for animal feeds.

Biofuels and other uses are projected to account for the remaining 22%.

These shares, however, differ across the different cereal types. While
wheat and rice is mainly used for food, feed use dominates maize and other
coarse grains.
 Consumption
Global use of cereals is projected to increase slightly from 2.8 Bln T in the
base period to 3.1 Bln t by 2032, driven mainly by higher food use
(+148 Mt), followed by feed use (+130 Mt). Asian countries will account
for near half of the projected demand increase.

Increased global consumption of cereals for feed is expected to be
dominated by maize (1.3%), followed by wheat (0.9%) and other coarse
grains (0.6%) over the next decade.

Wheat consumption is expected to be 11% higher in 2032 than in the
base period.

Four countries account for two-fifths of this increase: India, Pakistan,
Egypt, and China.

Global use of wheat for food is projected to increase by 57 Mt but to
remain stable at about 66% of total consumption; growth will be slower
compared to the previous decade as the rate of increase in world
population slows down.
Trade
Harvest Area
Since 1960, grain harvest area has increased
slightly while production levels have risen
dramatically.

Grain production has increased 269% since
1961.

However, grain harvest area has only increased
25%.

The increase of production and the significantly
smaller increase in harvest area are largely due
to the Green Revolution and the introduction of
high-yielding grain varieties.
 Harvest Area

World Grain Harvest Area
(1961-2010)

FAO, Worldwatch
 Factors Affecting Grain
Crops
The reliance on grain crops for food security is
threatened by extreme climatic events, especially
droughts and floods.

Around 375 million people will be affected by climate
change- related disasters by 2015.

By 2050, 10-20% more people will be subject to hunger
based on the changing climate’s effects on agriculture
and 24 million more children are expected to be
malnourished (21% more than if there were no climate
change).
 Factors Affecting Grain
Crops
The drought taking place in the Midwest and Great Plains of
the U.S. is considered the worst drought in 50 years,
coming close to matching the late 1930s Dust Bowl.

The drought is expected to cost billions of dollars and could
top the list as one of the most expensive weather-related
disasters in U.S. history.

The global market will be most affected by this drought,
because so much of the developing world relies on U.S.
corn and soybean production.

Food prices have already begun to increase due to
lower yields, and price fluctuations will inevitably affect
 The advantages of conservation tillage:
- Lower fuel costs
- Reduced labor requirements
- Enhanced soil quality
- Reduced levels of soil erosions (resulting in
more carbon remaining in soil)
- Improved levels of soil moisture conserving
- Reduced soil temperature fluctuations
Table 1. Carbon storage/sequestration from reduced fuel use with GM crops 1996–2020.
Fuel saving Permanent carbon dioxide savings arising Permanent fuel savings: as average family car
(million fromreduced fuel use (million kgof carbon equivalents removed fromthe road for a year
C rop/trait/country liters) dioxide) (‘000s)
HT soybeans

Argentina 4,433 11,837 7,844
Brazil 2,749 7,341 4,865
Bolivia, Paraguay, 899 2,401 1,591
Uruguay
US 1,687 4,503 2,984
Canada 255 681 451
HT maize
US 2,257 6,027 3,994
Canada 121 323 214
HT canola
C anada: G M H T canola 1,067 2,848 1,887
IR maize
Brazil 369 984 652
US/Canada/Spain/South 91 243 161
Africa
IR cotton – global 285 760 504
IR soybeans – South 449 1,199 795
America
Total 14,662 39,147 25,942
Table 2. Context of carbon sequestration impact 2020: car equivalents.
Additional carbon Potential additional soil carbon Soil carbon sequestration savings: as average
stored in soil (million kg sequestration savings (million kgof family car equivalents removed fromthe road
Crop/trait/country of carbon) carbon dioxide) for a year (‘000s)
HT soybeans

Argentina 1,832.5 6,725.2 4,445.8
Brazil 1,485.0 5,450.1 3,611.0
Bolivia, Paraguay, 490.7 1,800.8 1,193.1
Uruguay
US 110.9 407.0 269.6
Canada 62.9 230.7 152.9
HT maize
US 1,481.6 5,437.6 3,602.7
Canada 15.6 57.4 38.0
HT canola
C anada: G M H T canola 270.4 992.4 657.5
IR maize
Brazil 0 0 0
US/Canada/Spain/South 0 0 0
Africa
IR cotton – global 0 0 0
IR soybeans – South 0 0 0
America
Total 5,749.6 21,101.1 13,980.7
Food Prices

Romy Chammas, M.Sc.
Fall 2024
 Food Prices
Food prices are affected by several factors.

Weather and temperature
Crops are affected by the weather during their growing
season: too wet, too dry, too cold, or too hot => crops cannot
thrive.

A scarcity or shortage of a crop may increase its price to
consumers.

Good growing season results in a surplus, therefore food prices
may drop.

Pests and disease
 Food Prices
Transportation costs
When the price of oil and gas are high, it costs more to transport
from farm to plate (for example: to the processing facility or to the
store etc…)

Labor costs
The agri-food system requires a lot of working people ( farmers,
packers, processors, and retailers.)
 Other factors
Political and Economical situations can influence food
prices, either by increasing or decreasing them.

Conflicts
War
Economic Crisis
Inflation
Import/Export Restrictions …
 Global Food Prices
Trends & Prospects

Chapter 1: Agricultural and food markets: Trends & prospects

OECD/FAO (2023), OECD-FAO Agricultural Outlook 2023-2032, OECD
Publishing, Paris, https://doi.org/10.1787/08801ab7-en.
 Global Food Prices
Continuing a decade-long increase, global food prices rose 2.7%
in 2012, reaching levels not seen since the 1960s and 1970s.

Between 2000 and 2012, the global food price index increased
104.5%, at an average annual rate of 6.5%.
 The FAO Food Price Index (FFPI)
is a measure of the monthly
change in international food
prices.

For 2023, the index recorded
124.0 points, (13.7%) lower than
the average value in 2022.

https://www.youtube.com/watch?v=XiyZIFfwKmw
 Global Food
Prices
Some price volatility (instability) is strongly influenced by weather
shocks.

However, the recent upward trend in food prices and volatility can be
traced to additional factors including:
 Climate change
 Rising energy and fertilizer prices
 Poor harvests
 National export restrictions
 Rising global food demand
 Increasing demands for biofuel production
 COVID-19 impact (disruptions in supply chains, labor shortages,
and changes in consumer behavior)

As the effects of these shocks are largely unpredictable and
cannot be incorporated into the projections, prices in the Outlook
are assumed to return to their long-term trends, which
 Global Food Prices
International food price trends vary by commodity.

Global cereal and dairy prices have shown significant
volatility in recent years, whereas meat prices have
fluctuated less.

All food categories except for sugar and sweets experienced
smaller price increases through the first half of 2023 compared with
the same period in 2022.

All food categories increased in price in the first 6 months of
2023 compared with 2022, but the increases for meats (0.4%),
fresh fruits (0.4%), fish and seafood (0.7%), and fresh
vegetables (0.9%) were below their historical average price
increases.
 Cereal Prices
Due to the ubiquity of wheat, corn, and rice in global diets,
changes in the price of cereal grains generally affect consumers
more than fluctuations in other foods.

High cereal price volatility can have devastating consequences
for the world’s poor.

The food price spike, drove 44 million people into extreme
poverty.

High and volatile cereal prices can reduce income and increase
income instability.

High cereal prices are also associated with rising malnutrition as
poorer people are forced to eat cheaper, less-nutritious food, as
well as less quantities overall.
Cereal Prices
Since food prices began
increasing in the
early 2000s, cereal
prices have jumped
more than 80% and
exhibited significant
volatility due to
unfavourable weather
conditions, including
severe drought in the
U.S. and Eastern
Europe, drove cereal
prices up.

The grain price spike
continues due to the
COVID-19 pandemic
restrictions and prices
 Monthly prices for wheat, maize and barley

In 2022, the world wheat price averaged USD 319/t, the highest recorded in the past
20 years.
Prices increased sharply when Russia’s war against Ukraine started in February and
remained high for several months mainly driven by the uncertainty about supplies to
international markets.
With increased seasonal supplies from harvests in the northern hemisphere and an
agreement reached on the Black Sea Grain Initiative, prices started to fall before the
agreement was signed in late July 2022.

By early 2023, international wheat prices had fallen to their pre-war levels but remain
elevated.
 Cereal Prices
As cereal prices revert to their projected long-term trend, the co-movement of wheat
and rice prices will maintain or return to their historic ratio.

Prices for cereals in real terms are expected to decline over the next decade

FAO Cereal Price Index stood at 130.9 points in 2023, down 23.8 points (15.4
percent) from the 2022 record annual average, reflecting well supplied global
markets.
 Cereals in Lebanon?

The silos, which were hit by the blast and then gradually collapsed, had the
capacity for 120,000 tons of wheat and grains used to hold enough reserves for 6 –
12 months.

As a result, Lebanon is now unable to import large quantities of wheat as it has
nowhere to store it, posing a growing threat to Lebanon’s food security.

The reconstruction of the silos costs $10 billion

After Russia’s invasion of Ukraine, the nation agreed deals with Romania, Turkey and
Egypt to help meet its demand.

WFP, August 2020
 Meat Prices
Global meat prices have fluctuated less than cereal prices.

Meat prices increased slightly (5.5%) between July 2012 and January 2013
due to higher grain, and thus animal feed prices.

Beef prices, are less affected by cereal prices, since most global
beef production is pasture-based.
Pig meat and poultry prices show a strong link to feed costs as
their production uses more grain and protein meal-based feed.

Meat prices rebounded in 2021 and 2022, reflecting higher demand
following the economic recovery from the COVID-19 pandemic as well
as increased transportation and marketing costs.
 Medium-term evolution of animal-based commodity prices, in real terms

The FAO meat price index rose to average 118.8 in 2022, an increase of 10%
from the previous year. But In 2023, the FAO Meat Price Index averaged 114.6
points, down 4.2 points (3.5 percent) from 2022, due to increased export
availabilities from leading exporting regions.

As markets recover from these disruptions, supply chains stabilize, feed
costs decrease,
consumer spending on meat in middle-income countries resumes, prices
are expected to return to their long-term trend decline in real terms over the
next decade.

Pig meat prices are expected to decline more than prices for other meats
due to the recovery following the ASF (ASF: African Swine Fever) outbreak,
especially in China, Viet Nam, and the Philippines.
 Dairy Prices
International dairy prices exhibited significant volatility,
more than doubled in the period of 2006-2013 compared to
those between 1990-2005.

Total dairy trade increased, and per capita dairy
consumption increased as well.
Higher international prices in 2021 and 2022 were driven by: small trade
share, the dominance of a few exporters, and a widely restrictive
trade policy environment

The international market remains sensitive to sudden changes
in milk production because of low government stores in
the European Union and U.S.
 Dairy price ratios

International dairy prices are expected to fall in the short-term and
return to the longer-term pre-COVID-19 trend as supply chain disruptions
ease and marginal costs decline.

In 2023, the FAO Dairy Price Index averaged 118.8 points, down 23.6
points (16.6 percent) below the average for 2022, supported by lesser
import demand, reflecting price declines across all dairy products.
 Factors Affecting Global Food
Prices
The level and volatility of food prices in the last decade have been
influenced by various forces affecting global food supply and
demand.

 Population growth and increasing affluence –predominantly
in Asia– have led to rising food demand since 2000, which in
turn has triggered higher global food prices.

Between 2000 and 2010, Asia’s population grew 12%, from 3.7
billion to 4.2 billion people.
Asians accounted for 60% of the world’s population in 2023.
Meanwhile, salaries nearly doubled in Asia from 2000 to 2011.
However, salaries increased only 18% in Africa and 15% in
Latin America and the Caribbean.
 Factors Affecting Global Food
Prices

 Rising energy and fertilizer prices drove up food prices as
well.

 They added the costs of production, processing,
transportation and storage.

The average price of energy during 2000-2012 was 183.6%
higher than the average price during 1990-1999, while the
average price of fertilizer increased 104.8% in the same
period.
 Biofuels
Perhaps one of the most significant factors affecting global food
prices has been an increase in biofuel production in the last
decade.

Biofuels are produced through modern biological processes
like agriculture.

This is in contrast to the fuel produced by geological
processes which form fossil fuels (like petroleum and coal)
from decomposed plants and animals that have been
buried in the ground for millions of years.

When the source of the biofuel can regrow quickly, biofuels
are considered a form of renewable energy (unlike fossil
fuels).
 Biofuels
Biofuels have been around for a very long time.

At the start of the 20th century, Henry Ford planned to fuel his Model T
with ethanol, and early diesel engines were shown to run on peanut
oil.

However, discoveries of huge petroleum deposits kept
gasoline and diesel cheap for decades, and biofuels were
largely forgotten.

With the recent rise in oil prices, along with growing concern about
global warming caused by carbon dioxide emissions, biofuels
have been regaining popularity.

Much of the gasoline in the U.S. is blended with a biofuel:
 Biofuels and Global Food Prices

Using food crops for fuel (demand for biofuels) has led to an increase in global
food prices due to a significantly high demand for some agricultural commodities.

The high demand for some agricultural commodities, such as sugar, maize,
oilseeds and palm oil, has the potential to affect food security at both the
national and household levels mainly through its impact on food prices.

There has been a surge in the production of biofuels in Europe and the U.S. since
the early 2000s, backed by policies designed to cut use of fossil fuels.

An estimated 93 million tons of wheat and coarse grains, more than half of their
production, were used for ethanol production in 2007, double the level used in
2005.

If biofuel production continues to expand, the price of biofuel crops
(particularly maize, oilseed crops, and sugar cane) will continue to
increase.
 Biofuels and Global Food
Prices
Not only is biofuel production leading to rising food prices, but
there is also an association between biofuel production and
deforestation (removal of trees).

Agriculture is the largest cause of deforestation.

The removal of trees without sufficient reforestation has
resulted in damage to habitat, biodiversity loss,
extinction of species, climatic change, and dryness.

Deforestation also has adverse impacts on the
biosequestration of carbon dioxide.
 Biofuels and Global Food
Prices
Due to the negative impacts associated with biofuels, the
European Union agreed to limit the use of food-based
biofuels at 7% in 2015.

A new research study has shown that if the European Union cut
the use of biofuels to zero, then global vegetable oils
would be 8% cheaper by 2030.

Cutting the use of biofuels would lead to modest reductions in
global food prices, global poverty rates, and net global
welfare improvements.
 Conclusion

Food commodity prices were both higher and more volatile
in the last decade.

Food prices were driven up by climate change, extreme
weather events, production shocks, population growth,
increasing global affluence, and higher agriculture and
energy cost.

In recent years, recovery following the COVID-19 pandemic,
tight global supplies because of higher production costs and
Russia’s war against Ukraine reduced harvests of key crops.

Therefore, the high food prices tend to aggravate
poverty, food insecurity & malnutrition.
POPULATION GROWTH

Romy Chammas,
M.Sc.
Fall 2024-2025
https://www.youtube.com/watch?v=m
RcxGJcBDVo
 Population

Population: number of people
or inhabitants in a
particular region or country

Population growth is
measured by the difference
between the number of
births and number of deaths.
Population Global population
growth:
Every year, approximately
141 million people are born
and approximately 57 million
people die.

Therefore, around 84 million
people are being added to
the world population every
year.
Population

The main factors that affect population
growth are

Health (which Fertilit
in turn affects y
death)
Population
Health has improved over the long run, resulting in a dramatic
decline in mortality rates in the world.

As for fertility, socio-economic changes over the course of
modernization have contributed to a significant reduction in
fertility.

Decline in child mortality
Changes in the economy
Education
Availability of contraception
Rise in the status of and opportunities for women

Developed countries tend to have lower fertility rates than
developing countries
Population

Up to that point, birth
Beginning in the late
and death rates had
1700s, death rates
been relatively equal,
started to decline.
regardless of location.

A greater number of
people lived through
their adolescent
years, increasing the
average life
expectancy and
creating a new
trajectory for
population growth.
Life Expectancy

Estimates suggest that in a pre-modern, poor world, life expectancy was
around 30 years in all regions of the world.

In the 19th century, life expectancy started to increase in the early industrialized
countries while it stayed low in the rest of the world.

Factors that contributed to the increase in life expectancy:
Advancements in health and sanitation

New technologies in agriculture and production

Over the past 300 years, changes in the birth and death rates have resulted in
changes in population demographics within a country.
Life Expectancy
Life Expectancy Globally and by World Regions
(1770-2015)

James Riley For Data 1990 And
Earlier; WHO and World Bank For
 Demographic Transition
Demographic transition is the model that explains the changing
size of the total population as driven by two demographic
characteristics –birth rate and death rate– of the population.

As these rates change in relation to each other, their produced
impact greatly affects a country’s total population.

Within this model, a country will progress from one stage
to the next over time as certain social and economic
forces affect the birth and death rates.

Every country can be placed within the demographic transition
model, but not every stage has a country that meets its specific
definition.

 For example, there are currently no countries in Stage 1.
 There are arguably few countries, if any, in Stage 5, but there
is potential for reaching this stage in the future.
General note: A decline in death rate is followed by a
 Demographic Transition
Stage Long ago, the birth rate was high, but the death rate was also
1 high. Population size remained fairly stable. This describes the
reality throughout most of history. Societies around the world
remained in stage 1 for thousands of years.
Stage With the introduction of modern medicine, health slowly starts
2 to improve, so the death rate starts dropping. However,
fertility still remains as high as before. Families do not yet
adapt their fertility to the low mortality and continue to have many
children. Therefore, the population grows rapidly.
Stage Fertility declines steeply as a result of socio-economic changes,
3 and parents realize that the mortality of children is not as high as it
once was, opting for fewer births. Therefore, population growth
continues, but at a slower rate.
Stage The birth and death rates are both low. These countries tend to
4 have stronger economies, higher levels of education, better health
care, a higher proportion of working women, and a low fertility rate.
The result is a stable population.
Stage What happens at a very high level of socio-economic modernization
5 is still not clear. It is assumed that fertility will start to rise again (but
Demographic Transition
Impact of population aging on
food security in the context of
artificial intelligence: Evidence
from China

Chien-Chiang Lee, Jingyang Yan, Fuhao Wang
(Technological Forecasting and Social Change
Volume 199, February 2024, 123062)

https://doi.org/10.1016/j.techfore.2023.123062
Population Growth
In the years following World War II, population grew
fairly rapidly, with a rate of growth that peaked in the late
1960s at 2.1% per year.

Since then, population growth has gradually slowed,
and the number of people added annually has
changed little.

Every year sees the addition of about 84 million
humans on the planet.
Population Growth
World Population (1950-2014)

UNPD, Worldwatch Institute
Population Growth
Annual Growth Rate of World Population
(1950-2014)

UNPD, Worldwatch Institute
 Population
Growth
Having nearly tripled from 2.5 billion people
in 1950 to 7.3 billion in 2014, the human
population will continue to grow through 2070,
according to two recent demographic
projections.

After that, depending on which of the two
projections more accurately forecasts the
future, the human population will either:

 Continue to grow into the next century

 Begin to shrink
Population Growth
The two population projections

The other from the
One from the United
International Institute for
Nations Population
Applied Systems Analysis
Division (UNPD)
(IIASA)

 Both agree on how population has grown until now
 However, their future scenarios about population
growth are different
Population Growth
World Population to 2100, Two Projections

UNPD, Wittgenstein Centre, Worldwatch Institute
Population Growth
The United Nations Population Division (UNPD) demographers
used probabilistic projections, a methodology that applies past
behavior and expert opinion about the future to assign quantified
probabilities to various population outcomes.

Based on this, in 2014, they claimed that there was an 80%
likelihood that the world population would grow from 7.3
billion people to approximately 10.9 billion people in 2100.

The U.N. analysts reported that the most likely long-term future is
for continued growth into the 22nd century.
Population Growth
Demographers with the International Institute for Applied
Systems Analysis (IIASA), had an opposing opinion.

They have long used the probabilistic methodology, and foresee the
world population peaking around 2070 at 9.4 billion people
and then gradually shrinking to 8.9 billion by the century’s
end.
 Population Growth
What explains the disagreement between these two respected groups of
population projectors?

 Different assumptions, revolving mostly around two topics: the African population
and the future of education

The U.N. demographers stressed that recent surveys have shown that human
fertility is not falling in a number of countries as earlier projections had assumed
they would.

Most of these countries are in Africa, and the UNPD significantly increased its earlier
projections for that continent’s population.

The new probabilistic projections gave an 80% chance that the African
population will rise from 1.2 billion today to somewhere between 3.5-5.1
billion by 2100.
 Population Growth
The IIASA demographers, by contrast, focused not on recent
fertility trends, but rather more on educational ones.

In every region of the world, including Africa, there are larger
proportions of young people enrolled in school, and these rates are
likely to continue to rise.

Since high levels of education are associated with reductions in
fertility, the demographers reasoned that fertility, even in high-fertility
countries, is likely to fall more than current fertility trends.

This different focus led in particular to opposing projected paths for
the population in Africa, with the IIASA projecting a population of
2.6 billion by 2100 (in contrast to 3.5-5.1 billion projected by
the UNPD).
Population Growth
Africa’s Population to 2100, Two Projections

UNPD, Wittgenstein Centre, Worldwatch Institute
Population Growth
The differences in the two groups’ projections for
other world regions are less dramatic.

Since education levels are already fairly high in
the other world regions, fertility has already
fallen considerably in recent decades in the rest
of the world.

Therefore, there is less division on where
population in those regions is likely to go.
Population Growth
The two groups’ best-guess projection for the population in 2100 in
the world’s major regions are as follows:

For Asia, the UNPD projects 4.7 billion people in 2100, while IIASA projects
4.4 billion.

For Europe, UNPD projects 639 million, while IIASA projects 702 million.

For North America, UNPD expects 513 million, while IIASA projects 520
million.

For South America and the Caribbean, UNPD projects 736 million, and
IIASA expects 684 million.
Modern Challenges in
Water, Nutrition & Climate
Change

Romy Chammas - MSc.
Fall 2024 - 2025
 Introduction
Nowadays, there are many challenges facing
society that affect people’s health and
lives:
Water availability and quality
Greenhouse gas emissions

Food wasting
Malnutrition
 Water- Where is All the
Water?
Most of the water on earth is salty water:
97.5%.

The remaining 2.5% is fresh water
( farming, industry, at home, for drinking, washing
and watering).

However, 70% of fresh water is frozen
(mostly as ice in Antarctica), and nearly
30% is found underground (too expensive
to tap into and filter.)

That leaves only around 1% of all the fresh
water on Earth to use to grow crops, raise
animals, power industry, and use at
home
Where is All the
Water?
Water in the Human
Body
 Water Issues
There is a lot of water in the food we eat (embodied
water).

For example: it takes approximately 25,000 L (half a
garden swimming pool) to produce enough food for a
family of 4 for one day.

More than 2 billion people do not have access to
clean drinking water.
Many people walk at least 2 hours a day to get water.
Water in Lebanon
One of the most precious resources in Lebanon.

Key obstacles:
 Increasing water demand from all sectors
 Unsustainable water management practices
 Water pollution

Meeting the country’s water demand poses a significant
challenge to the government.

To meet the domestic water demand in 2030, Lebanon
will have to supply 420 million m3 compared to the 280
million m3 supplied in 2005.
 Water in Lebanon
The driving forces affecting the quality and
quantity of water resources in Lebanon are:

 Population growth
 Urbanization
 Economic growth
 Climate change
Water in Lebanon
Population
growth

World Data.info
 Water in Lebanon
1. Population growth:
In assessing water resources, it is important to consider the
total population in Lebanon (including refugees) and
not just the resident population to capture the full impact
on water resources.

Further pressure on water resources comes from tourism.
According to the Ministry of Tourism, 1.35 million visitors
came to Lebanon in 2023.

Tourists consume more water than residents (400 L/c/d
for tourists compared to 150 L/c/d for residents) but over a
short time period.
Water in Lebanon
2. Urbanization:
Lebanon is a heavily urbanized country, with 88% of the
population living in urban areas.

It is estimated that Lebanon’s urban areas will grow by 10
km2 per year over the next 30 years which will stress water
resources.

The growing urbanization has also resulted in increased
levels of untreated wastewater and solid waste,
particularly in the coastal region, leading to untreated
 Water in Lebanon
3. Economic growth:
Lebanon’s economical development has been the main
driver of urbanization in the country across the years.

During the 19th century, Lebanon was largely an agrarian
country.

Throughout the 20th century, the contribution of the
services sector to overall economic growth increased
in Beirut and the other major cities in Lebanon.

The main drivers of this growth were construction &
reconstruction, tourism, and banking.
 Water in Lebanon
3. Economic growth
The agricultural sector continues to be the largest
water consumer in the country. About 60% of total
freshwater goes to agriculture.

As a result of the pattern of economic growth, agricultural
demand on water resources will grow by 1% per year
over the next 20 years, while domestic and industrial
 Water in Lebanon
4. Climate change:
Global warming affects precipitation. This will be reflected in
changes in freshwater availability and quality.

Some studies argue that Lebanon is witnessing signs of
decreasing precipitation and increasing drought and
desertification.
There is a clear trend and a substantial decline in precipitation
between 1966 and 2005.
Precipitat
ion (mm)

Year Shaban
Water in Lebanon
4. Climate change:
As most climate experts predict, the dry areas will become
drier as the earth continues to warm up.
The Litani River basin is going to see less rain in the future,
which will have a substantial impact on water resources for
irrigation because the Litani River is the lifeline for
agriculture in the Bekaa and South Lebanon.

Moreover, snow coverage and density have been declining.

The effect of global warming on snow, which is vital for
water resources in Lebanon, is devastating.

It is predicted that with a rise of 2°C, the snow cover in the
 Greenhouse Gases
Greenhouse gases trap heat in the
atmosphere and make the planet
warmer (global warming).

The main greenhouse gases
include carbon dioxide (CO2),
methane (CH4), nitrous oxide
(N2O), and water vapor (H2O gas).

Human activities are responsible
for almost all of the increase in
greenhouse gases in the
atmosphere over the last 150
years.
Greenhouse Gases
 Greenhouse Gases- CO2
Emission
Carbon dioxide (CO2) is released through the
natural respiration and volcanic eruptions.
It also enters the atmosphere through human
activities.
 Burning fossil fuels (coal, natural gas, and oil),
solid waste, trees and wood products
 Manufacturing cement

The increasing atmospheric CO2 concentration is
the most important ‘force’ of climate
change.

CO2 is removed from the atmosphere when it is
absorbed by plants as part of the biological
Greenhouse Gases- CO2
Emission
 Greenhouse Gases and Global
Warming
The consequences of the greenhouse gas effect are difficult to
predict, but certain events seem likely:

On average, the Earth will become warmer. Some regions may
welcome warmer temperatures, but others may not.

Warmer conditions will probably lead to more evaporation and
precipitation overall, but individual regions will vary, some
becoming wetter and others dryer.

A stronger greenhouse effect will warm the oceans and
partially melt glaciers and ice, increasing sea level. Ocean
water will also expand if it warms, contributing further to sea
level rise.

Higher temperatures and shifting climate patterns may
 Food Wastage
“Are we feeding the hungry or feeding the waste?”

Food inequality is a key social problem.

Rich and wealthy have the freedom to discard excess food
into the trash bins, the same amount of food wasted (1.3
billion tons lost annually) can feed the malnourished 4 times!

A statistical report revealed that around 828 million people
worldwide suffer from hunger and malnutrition (2024 UN
World Hunger Report), translating to 1 in 9 people suffering from
malnourishment, with the main sufferers being children.

Theoretically, this phenomenon can be avoided with equal
distribution of food, where excess doesn’t end up in landfills,
but feed hungry people.
Obesity
Overweight and obesity cause a number of chronic health
problems: diabetes, high blood pressure, heart attacks,
stroke, breathing problems (sleep apnea), osteoarthritis,
and cancer.
Their rates are increasing worldwide and leading to a rising
number of deaths.
About 2.2 billion people around the world are either
overweight or obese.
According to 2017–2018 data from the National Health
&Nutrition Examination Survey (NHANES)
Global obesity rates have almost tripled while overweight
has more than doubled since 1975.
From 1999 –2000, US obesity prevalence increased from 30.5%
to 41.9%.
 Obesity
The fundamental cause of obesity and overweight is
an energy imbalance between calories consumed and
calories expended.

Globally, there has been:
 Increased intake of energy-dense foods that are
high in fat
Obesity

Ng. et al.
 Malnutrition is Costly
Malnutrition results from either nutrient
deficiency/undernutrition (wasting, stunting,
underweight) or overconsumption (overweight or
obesity).

Malnutrition also impact the social and economical development
of countries

It is estimated that malnutrition in all its forms could cost society
up to $3.5 trillion per year, with overweight and obesity alone
costing $500 billion per year.

Undernutrition costs the global economy $1.4-2.1 trillion per
year and explains around 45% of deaths among children
under the age of 5.
Malnutrition is Costly
Food Security &
Sustainability
-Introduction-

Romy Chammas MSc.
Fall 2024- 2025
Where does food come
from?
 Food Security
Availability and adequate access to sufficient,
affordable, safe, nutritious food at all times in order to
maintain a healthy and active life.

Food security analysts look at 3 main elements:

Food availability: available in sufficient quantities and on a
consistent basis. This includes stock and production in a
given area and the capacity to bring in food from elsewhere.

Food access: People must be able to regularly obtain
adequate quantities of food, whether through purchase,
home production, trade etc...

Food utilization: Consumed food must have a positive
 Food Sustainability
A system that delivers food and nutrition security for all in such a way
that it enhances the environmental, economic, and social health of a
particular place.

Moreover, the environmental, economic, and social bases to
generate food security for future generations are not
compromised.

Sustainable agriculture is regenerative and self-sustaining.
It produces its own inputs (fertilizer, feed) and manages its outputs (crop,
waste, manure) in a closed loop cycle.

It contributes to soil fertility, clean water systems, biodiversity and
other ecosystem services, rather than depleting them.

A sustainable food system is climate-smart and simultaneously
increases agricultural productivity, enhances climate resilience, and
reduces greenhouse gases in agriculture.
Future Challenges for
Feeding the World
World Projected Acreage Under
Population Caloric Cultivation
(Billions of Consumption (Billions of Acres)
People) (Trillions Kcal/d) 4
3 3.4 3.56
27 3.
0 4 3.6
5
2 20
3
5
14 2.
2 5
0 2
1 1.
5 5
1 1990 2015 1
1960 1990
0 2050 0. 2000
5
5
0
0
 Despite Progress, Many
Remain Hungry
35
0
30
0 1990-1992
People (Millions) 25 Increasing
2014- 2016
Malnourished

0
Number of

20
0

15
0
Increasing
10
5
00

0 South SSA SE LAC MENA
Asia Asia
Prevalence of hunger declined from 19% to 11% (1990-2015).
According to the latest research by the Food and Agriculture Organization (FAO),
828 million people are hungry in the world.
FAO
 Zero Hunger Challenge
The Zero Hunger Challenge was launched by United
Nations Secretary-General Ban Ki-moon in 2012.

Part of the 2030 Agenda

It reflects 5 elements, which taken together, can end
hunger, eliminate all forms of malnutrition, and build
food systems.
Pathways to Zero Hunger, Zero Hunger Challenge,
 Zero Hunger Challenge
How is the 2030 Agenda implemented?

In September 2015, the 193 Member States of the United Nations adopted the
Sustainable Development Goals (SDGs), a set of 17 aspirational
objectives which will guide the actions of governments, international
agencies, civil society and other institutions over the next 15 years (2016-
2030).

The ambitious 2030 Agenda is a global vision for people, for the planet,
and for long-term prosperity.

The 17 SDGs integrate the three dimensions of sustainable development:
economic, social and environmental – with closely interwoven targets.

The SDGs are universal for all countries. The 2030 Agenda is as relevant
to developed & to developing nations.

https://www.youtube.com/watch?v=Be_790O8AlU
Zero Hunger Challenge, United
Sustainable Development Goals
(SDGs)
Ensure inclusive and
End poverty in all its quality education for all
forms everywhere. and promote lifelong
Almost 80% of poor learning.
people
live in rural areas. Nutritious food is critical to
learning.

End hunger, achieve
food security and
enhanced Achieve gender equality and
nutrition, and empower all women and
promote girls. Women produce 1/2
sustainable the world’s food but have
agriculture. much less access to land.
We produce food for
everyone, yet Ensure access to water and
almost 800 million sanitation for all.
go hungry. Sustainable agriculture
Sustainable Development Goals
(SDGs)
Ensure access to Land reforms can
affordable, reliable give fairer access
and sustainable to rural land.
energy for all.
Modern food systems
are heavily
dependent on fossil
Make cities
fuels.
inclusive, safe,
resilient and
Agricultural growth in sustainable.
low- income Rural investment
economies can can prevent
reduce poverty by unmanageable
half. urbanization.

Build resilient
infrastructure, Ensure
promote sustainable sustainable
industrialization and consumption
Sustainable Development Goals
(SDGs)
Take urgent action to Promote just and
combat climate peaceful
change and its impacts. societies.
Agriculture is key in Ending hunger can
responding to climate contribute greatly to
change. peace and stability.

Revitalize the global
Conserve and
partnership for
sustainably use the
sustainable
oceans, seas and
development.
marine resources.
Partnerships help
Fish gives 3 billion raise the voice of
people 20% of their the hungry.
daily animal protein.

Sustainably manage forests,
SDG 2: End Hunger and
Malnutrition

End hunger, achieve food security and
enhanced
nutrition, and promote sustainable
agriculture.
We produce food for everyone, yet around
800 million people go hungry.
 SDG 2: End Hunger and
Malnutrition

SDG 2 aims to end hunger and all forms of malnutrition by
2030.

It also commits to universal access to safe, nutritious,
and sufficient food at all times of the year.

This will require:
 Sustainable food production systems
 Equal access to land
 Markets and international cooperation
 Technology to boost agricultural productivity
 SDG 2: End Hunger and
Malnutrition
The fight against hunger has progressed over the past 15
years.

Globally, the prevalence of hunger has declined, from 15%
according to figures for 2000-2002, to 11% according to
figures for 2014-2016.

However, over 828 million people worldwide remain
hungry and
lack regular access to adequate amounts of dietary energy.

If current trends continue, the ‘zero hunger’ target will be
largely missed by 2030.
 SDG 2: End Hunger and
Malnutrition
Globally, in 2024, nearly 1 in 3 children under the age of
5 (> 159 million children) had stunted growth.

Stunting:
Inadequate height for age
An indicator of the cumulative effects of
undernutrition and Infection

Another aspect of child malnutrition is the growing amount
of children who are overweight, a problem affecting nearly
every region.
 Conclusion
Ending hunger and malnutrition relies heavily on sustainable
food production systems and resilient agricultural
practices.

A sustainable food system also increases agricultural
productivity and improves climate resilience.
Organic Agriculture

Romy Chammas MSc.
Fall 2024
Why Organic?

https://www.youtube.com/watch?v=lRy
XlvIJFWI
 Organic
Agriculture
Organic agriculture is a sustainable farming system that
produces healthy crops and livestock without damaging
the environment.

This system relies on ecosystem management rather
than external agricultural inputs.

Organic agriculture considers potential environmental and
social impacts by eliminating the use of synthetic
inputs, such as:
Synthetic fertilizers & pesticides, veterinary drugs,
genetically modified seeds and breeds, preservatives,
and irradiation.
 Organic Agriculture
There are few research studies that examine the effect of
organic agriculture on human health.

However, there are many studies that have shown the
heavy negative impacts of non-organic food and
conventional farming on human health.
 Pesticides
Pesticides are chemical substances that are meant to kill pests,
which are insects or other organisms that are harmful to
cultivated plants or animals.

Most pesticides are intended to serve as crop protection
products, which in general, protect plants from weeds, fungi,
insects, or other pests that feed on crops.

Pesticides can be grouped according to the types of pests they
kill:
Insecticides: kill insects
Herbicides: kill plants (weed- herbs)
Fungicides: kill fungi
Bactericides: kill bacteria
Rodenticides: kill rodents (rats and mice)
Larvicides: kill larvae
 Pesticid
es

Although pesticides protect crops, they could cause serious
harm to human health.

DDT is carcinogenic and was banned in the U.S. in 1973.

There are over 400 chemical pesticides that are regularly
used in conventional farming.

Some crops are sprayed up to 16 times with 36 different
pesticides.
 Pesticide
s
Organophosphates
The most dangerous and the most widely used.
They account for about ½ of the pesticides used in the U.S.
Cheap cost and broad spectrum of uses
Almost 30,000 tons are applied annually

Very poisonous and were used in World War II as nerve
agents
Headache, dizziness, muscle twitches, nausea, stomach
pain, weakness, shortness of breath, anxiety, diarrhea,
convulsion, coma
 Pesticides
Endocrine Disrupting Chemicals (EDCs)
A number of pesticides are suspected or proved to act as
endocrine disrupting chemicals (EDCs);

EDCs interfere with the steps of hormone signaling.

They may affect genes in a way similar to estrogen and have
been also known as “gender benders.”

Even small doses can affect the sexual characteristics of
animals.

EDCs have been suspected to be associated with altered
reproductive function in males and females, increased incidence
of breast cancer, abnormal growth patterns,
 Environmental Impact- Water
In addition to the harmful Pollution
effects of chemically-infused crops on
human health, non-organic conventional farming has harmful
impacts on the environment.

Conventional agriculture is the largest source of water
pollutants (pesticides & fertilizers)

Pesticides from every chemical class have been detected in
groundwater and especially beneath agricultural areas.

They are also widespread in the surface waters

Eutrophication and “dead zones” due to nutrient runoff
affect many rivers, lakes, and oceans.

Reduced water quality impacts agricultural production,
 Environmental Impact- Climate
Change

Synthetic fertilizers used in conventional agriculture produce
more greenhouse gases, contributing to global warming.

Conventional agriculture relies on synthetic nitrogen
fertilizers, whose production results in the release of nitrous
oxide, an extremely potent greenhouse gas, with a much
greater warming potential per unit released than carbon.

Organic farming fights climate change by:
 Reducing greenhouse gas emissions
 and traps temperature-raising carbon in soil, keeping
it from contributing to the greenhouse effect.
 Environmental Impact- Climate
Change
Soil from organic farms is 26% better at retaining carbon (for
longer periods of time) than soil that's farmed with
conventional methods and synthetic fertilizers.

Reason: The matter that organic farmers use (compost,
green manure, animal matter… as well as the living
things in healthy soil, such as microorganisms,
earthworms, and other components— give soil humic
acids.

Humic acids provide the soil with the ability to retain
carbon over the long-term better than conventionally farmed
soil.

Organically farmed soil contains 44% more humic
Environmental Impact- Climate
Change
Organic farming not only acts to reduce greenhouse
gas emissions, but it actually acts as a sink for carbon
by sequestering CO2.

 If all U.K. farming was converted to organic, at least 1.3
million tons of carbon would be taken up by the soil each
year. That’s the equivalent of taking nearly 1 million cars off
the road!

Moreover, organic agriculture uses up to 50% less fossil
fuel energy than conventional farming.

Common organic practices—including rotating crops,
applying mulch to empty fields, cover cropping and
maintaining trees on farms—also stabilize soils and
Cover cropping

Composting Mulching
 Organic Agriculture and
Biodiversity
Organic farming is beneficial for wildlife and biodiversity.

Organic farms have 30% more species on average than non-
organic ones.

This greater biodiversity includes birds, insects, plants,
and microbes.

The use of pesticides has threatened wildlife and
biodiversity.

 For example, vast numbers of insects, including helpful
 Organic Livestock
Production
Livestock are a major contributing factor to the success of
organic agriculture.

They play an important role in maintaining the fertility of
grasslands.

They feed on home-grown organic feed and their manure is
returned to the crops around the farm (same land that produces
the feed).

A system involving grassland and livestock is likely to be the most
sustainable system of organic production.

Animal husbandry stabilizes the agro-ecological system.
 Organic Livestock
Production
Organic livestock are fed organically produced grass and
meals.

Livestock must have access to free range exercise area and
grazing (maximum access to pasture).

Genetically modified organisms and crops are not
compatible with organic production.

Chemically synthesized medication is not permitted for use on
the livestock, but sick and injured animals must be treated
immediately because the well-being of the animal is more
important than keeping the animal organic.

Animal housing satisfies the needs of the animals, including
 Organic Livestock
Production
In non-organic agriculture, antibiotics are added to the
animal feed or drinking water of livestock to prevent
infection/disease, to help them gain weight faster (speed up
animal growth) or use less food to gain weight.

The use of antibiotics in livestock can bring antibiotic-resistant
bacteria to humans via consumption of meat and through
airborne bacteria.

Antibiotics are also sprayed onto fruit trees to prevent and
treat infection.

Traces of antibiotics that remain after the initial spraying may
encourage emergence of resistant strains of bacteria.
 Non-Organic, Conventional
Agriculture
Advantages of conventional, non-organic farming:
Lesser costs, higher gains
Unlike organic farmers, who use compost and animal manure
which are expensive to ship, conventional farmers use
synthetic chemical fertilizers and sewage sludge that are
cheaper.
Also, they can make use of a larger area of land to plant their
crops.

Increase in food production
Since production costs of conventional farming are lower,
farmers are able to produce more crops and as a result,
meet the growing demand for food supply.
Conventional farming produces larger quantities of food as
 Non-Organic, Conventional
Agriculture

(Cont’d) Advantages of conventional, non-organic farming:

Lower costs of produce
Because of low production costs, conventional farmers are able
to mass-produce their crops and sell them to consumers at
lower prices.

As an effect, there are more choices for the buying public
because competitors are urged to lower their prices to be
competitive. This becomes a win-win situation for both the
farmers and the consumers.
 The World of Organic Agriculture
Statistics and Emerging Trends 2023

Research Institute of Organic Agriculture FiBL and IFOAM –
Organics International

Edited by Helga Willer, Bernhard Schlatter, and Jan Trávníček
 Global Organic Production
The modern organic farming movement emerged in the
1950s-1960s, largely as a reaction to consumer
concerns over the use of agrochemicals.

The period after World War II and through the 1950s is
commonly known as the “Golden age of pesticides”
because the use of agricultural chemicals was widespread
and their effects were largely unknown.

As the health and ecological consequences of agrochemicals
began to be understood, governments started to regulate
their use and consumers started to demand organically
certified foods
 Global Organic Production
The latest available data on organic agriculture
worldwide show that 2021 was another good year
for global organic agriculture.

Organic farmland and retail sales continued to
grow and reached another all-time high.

In 2021, the global organic production area
amounted to approximately 76.4 million hectares.
This constitutes an increase of almost 40 million
hectares in 10 years.
Global Organic Production
 Global Organic Production
More than 76.4 million hectares of organic farmland in
2021:

The regions with the largest organic agricultural land areas
are:

-Oceania (36 million hectares – almost half the world’s organic
agricultural land, 47%),
- Australia (35.7 million hectares),
- Europe (17.8 million hectares, 23%),
- Latin America had 9.9 million hectares (13%),
- Asia (6.5 million hectares, 8.5%),
- Argentina (4.1 million hectares),
- Northern America (3.5 million hectares, 4.6%),
- France (2.8 million hectares),
- Africa (2.7 million hectares, 3.5%)
 Global Organic
Farming
Organic Agricultural Land by
Region (1999-2010)

Willer and Kilcher, The World of Organic
Global Organic Production
Global Organic Production
Organic Agricultural Land by Region
(2021)
Global Organic Production
Organic Agricultural Land by Country
(2021)
 Global Organic Production
In 2021, 1.6% of the world’s agricultural land was
organic.
The highest organic shares of the total agricultural land
were in Oceania (9.7%) and in Europe (3.6%; EU: 9.6%).

There were at least 3.7 million organic producers in
2021.
49% of the world’s organic producers are in Asia, followed
by Africa (31%), Europe (12%), and Latin America (8%).

The countries with the most producers are India
(1,599,010), Uganda (404,246), and Ethiopia (218,175).

There has been an increase in the number of producers of
more than 170,000, or 4.9%, compared to 2020.

In 2022, 74 countries had fully implemented
regulations on organic agriculture.
 Global Organic Food Sales
Organic food sales reached nearly 125 billion euros in 2021.

The countries with the largest organic markets were the United
States (48.6 billion euros), Germany (15.9 billion euros), and France
(12.7 billion euros).

Growth in the global market for organic food slowed in 2021.
Geopolitical conflicts and rising food prices exerted a
negative impact on the global organic food market.

After reporting record sales in 2020, market growth slowed in
2021. Lower growth is projected for 2022 as consumer demand
weakens.
Inflation, especially high food prices, and food security
concerns are affecting demand for organic foods.

The European market has been the most adversely
affected.
Organic Agriculture: Key
Indicators

FiBL survey 2023, based on national data sources, data from certifiers and IFOAM – Organics
International
Organic Agriculture: Key
Indicators

FiBL survey 2023, based on national data sources, data from certifiers and IFOAM – Organics
International
Organic Agriculture Globally

FiBL survey 2023
 Organic Farming
Sustainable agricultural practices of organic
farming are relatively labor-intensive and have
the potential to contribute to long-term
employment in rural areas.

Approximately 80% of the global organic
farmers live in developing countries.
 Organic Farming

While organic agriculture often produces lower yields, it
can outperform conventional practices—especially
in times of drought—when the land has been farmed
organically for a longer time.

Conventional agricultural practices often degrade
the environment over both the long-term and the
short-term through excessive water use, soil
erosion, and biodiversity loss.

However, increased yields alone in conventional
farming are not meeting the needs of people around
the world.
Globally, approximately 1 billion people suffer from
food insecurity—due to issues of distribution,
individual purchasing power, storage,
refrigeration, and market access, among others—
with sub-Saharan Africa being the region most affected
 Organic Farming
Organic farming also reduces vulnerability to
climate change and enhances biodiversity.

Organic farming in Africa is now being recognized as
a way to address problems of food insecurity
and climate change.

Organic farming is being used to restore soils,
which in turn has resulted in higher food crop
yields, greater household food security, and
increased incomes.

A combination of traditional and organic farming
techniques have allowed farmers in Burkina Faso to
adapt to climate change and build resilience to
weather shocks.
 Organic Farming
In Ethiopia, organic farming methods have helped
farmers use water more efficiently and restore soil
health to better withstand harsh weather
conditions like drought, while increasing crop
yields and improving food security.

In Cambodia, on the other hand, negative impacts of
conventional farming systems on the environment and
on farmers have resulted in widespread conversion to
organic agriculture.

Health indicators, such as a large reduction in
pesticide poisoning-related symptoms, improved
among Cambodian farmers who adopted organic
techniques.
In Conclusion
Organic agriculture is a production system that relies on
ecological processes rather than the use of synthetic inputs,
such as chemical fertilizers and pesticides.

It promotes biodiversity, biological cycles, and soil biological
activity (quality).

Organic farming focuses on optimization rather than
maximization of production.

As a result, there are lower production levels than in
conventional systems.