Practical Pollution PDF Microbiology 2024/2025

Summary

This PDF document details an introductory chapter on pollution, focusing on microbiology. It covers various types of pollution, including air pollution, from different sources and provides a basic understanding of the different levels of impact linked to pollution.

Full Transcript

1 Pollution Microbiology 2024/2025

Environmental pollution
Air pollution occurs when harmful substances, including
particulates and biological molecules, are introduced
into Earth's atmosphere.
These substances harm living organisms.

oise, therma
r,n l, li
gh
te
a t
w

po
il,
so

llu
tion
Air,

Air Pollution
Defintion
Air pollution occurs when harmful substances,
including particulates and biological molecules, are
introduced into Earth's atmosphere. These substances
harm living organisms

Types of air Pollutants

Primary Pollutants Secondary Pollutants
Directly emitted from Form in the atmosphere
a process such as ash from chemical
from a volcanic reactions involving
eruption primary pollutants

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 2

Major primary pollutants produced by human
activity

Pollutant Source Impact

Volatile organic Methane, Ozone Formation,
compounds (VOCs) Non-Methane Cancer Risks

Burning of fossil
CO2 Global warming
fuels

Incomplete
CO Toxicity
Combustion

Volcanoes and in
SOx various industrial Acid rain
processes

NOx High Temp. Acid rain

Secondary pollutants include:

Pollutant Source Impact

Peroxyacetyl nitrate NOx, VOCs. CO2 &
Warming Earth
(C2H3NO5) Greenhouse gas

vehicular and Photochemical
Particulates (PM)
industrial emissions smog

(NOx) & Volatile
Ozone (O3) Organic Compounds warming Earth
(VOCs)

©️Mahmoud Alaa
3 Pollution Microbiology 2024/2025

Effects of Air Pollution on Plants

Effects of Air Pollution on Plants
Air pollution can damage plants, causing necrotic
lesions (dead tissue) or yellowing (chlorosis) of
leaves. This reduces growth and can be fatal with
repeated exposure.

Oxidants
Ozone is a major pollutant in oxidant smog, first
noticed in Los Angeles in 1944 and widely
documented in North America, including Ontario.
Ozone levels vary, especially in July and August,
influenced by air flows from urban and industrial
areas. High ozone levels cause flecking, bronzing, or
bleaching on leaf surfaces.
Sensitive Plants:
White beans, cucumbers, grapes, green beans,
lettuce, onions, potatoes, radishes, rutabagas,
spinach, sweet corn, tobacco, and tomatoes show
more symptoms of ozone damage. Resistant plants
include endive, pear, and apricot.

Factors Influencing Ozone Injury:
Susceptibility to ozone damage depends on
environmental factors and plant growth conditions:
High relative humidity
Optimal soil-nitrogen levels
Water availability
The age of leaves: younger leaves are initially
resistant, becoming susceptible as they grow, then
resistant again at full maturity

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 4

Sulfur Dioxide
Sources:
Major sources include coal-burning operations
(electric power, space heating), burning petroleum,
and smelting sulfur-containing ores.
Entry into Plants:
Sulfur dioxide enters leaves through stomata
(microscopic openings).
Types of Injury:
1. Acute:
Caused by high concentrations of sulfur dioxide
in a short time.
Symptoms: 2-sided (bifacial) lesions between leaf
veins or along margins.
Necrotic areas can vary in color from light tan to
orange-red or brown, depending on time of year,
plant species, and weather.
Most sensitive: Recently expanded leaves;
youngest and oldest leaves are more resistant.
2. Chronic:
Long-term absorption of sublethal
concentrations.
Symptoms: Yellowing (chlorosis) or bronzing on
the underside of leaves.
Sensitivity varies among species, varieties, and
even individuals due to geographical location,
climate, growth stage, and maturation.
Susceptible Crop Plants:
Alfalfa, barley, buckwheat, clover, oats, pumpkin,
radish, rhubarb, spinach, squash, Swiss chard, and
tobacco.
Resistant Crop Plants:
Asparagus, cabbage, celery, corn, onion, and

©️Mahmoud Alaa
5 Pollution Microbiology 2024/2025

Fluoride
Sources:
Combustion of coal
Production of brick, tile, enamel frit, ceramics, and
glass
Manufacture of aluminium and steel
Production of hydrofluoric acid, phosphate
chemicals, and fertilizers
Effects on Plants:
Fluorides absorbed by leaves move towards the
margins of broad leaves and tips of
monocotyledonous leaves.
Little injury at the site of absorption, but injurious
concentrations build up at leaf margins or tips.
Injury starts as gray or light-green water-soaked
lesions, turning tan to reddish-brown.
Necrotic areas expand inward to the midrib on broad
leaves and downward on monocotyledonous leaves.
Plant Susceptibility:
Sensitive species: Apricot, barley, blueberry, peach,
gladiolus, grape, plum, prune, sweet corn, tulip.
Resistant species: Alfalfa, asparagus, bean (snap),
cabbage, carrot, cauliflower, celery, cucumber,
eggplant, pea, pear, pepper, potato, squash,
tobacco, wheat.

Ammonia
Sources:
Accidents involving storage, transportation, or
application of anhydrous and aqua ammonia
fertilizers.

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 6

Effects on Plants:
Injury appears as irregular, bleached, bifacial,
necrotic lesions.
Grasses show reddish, interveinal necrotic streaking
or dark upper surface discoloration.
Flowers, fruit, and woody tissues usually unaffected.
Severe injury to fruit trees can lead to recovery
through new leaf production.
Plant Susceptibility:
Sensitive species: Apple, barley, beans, clover, radish,
raspberry, soybean.
Resistant species: Alfalfa, beet, carrot, corn,
cucumber, eggplant, onion, peach, rhubarb, tomato.

Particulate Matter
Sources:
Cement dust, magnesium-lime dust, carbon soot
Effects on Plants:
Inhibits normal respiration and photosynthesis within
leaves
Causes chlorosis and death of leaf tissue through
crust formation and alkaline toxicity in wet weather
Affects the action of pesticides and agricultural
chemicals
Increases soil pH, adversely affecting crop growth

Ozone Depletion
Ozone Layer:
Located in the stratosphere, it filters out harmful
shortwave ultraviolet (UV) radiation

©️Mahmoud Alaa
7 Pollution Microbiology 2024/2025

Causes:
Depletion caused by ozone-depleting substances
such as chlorofluorocarbons (CFCs)
These substances break down ozone, allowing
more UV rays to reach Earth
Impacts:
Increased UV exposure can affect humans,
animals, and plants, causing sunburn, skin cancer,
cataracts, plant damage, and reduction in plankton
populations
Phenomena:
Steady decline of ~4% in stratospheric ozone since
late 1970s
Larger springtime decrease in ozone around polar
regions (ozone hole)
Mechanisms:
Catalytic destruction of ozone by atomic halogens
from man-made halocarbon refrigerants, solvents,
propellants, and foam-blowing agents
These compounds are transported into the
stratosphere by winds after emission at the surface
Response:
Montreal Protocol: Bans production of CFCs,
halons, and other ozone-depleting chemicals
Concerns:
Biological consequences from increased UV
exposure due to ozone depletion

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 8

©️Mahmoud Alaa
9 Pollution Microbiology 2024/2025

Ozone Layer Depletion and UVB Radiation
The ozone layer absorbs UVB ultraviolet light from the
sun, When the ozone layer is depleted, surface UVB
levels increase, potentially causing damage like higher
skin cancer rates. This concern led to the Montreal
Protocol.
Stratospheric ozone decreases are linked to CFCs
and higher surface UVB levels.
No direct observational evidence connects ozone
depletion to increased skin cancer and eye damage,
partly because UVA (also linked to skin cancer) is not
absorbed by ozone, and lifestyle changes over time
complicate statistical analysis

Increased UV Radiation and Ozone Depletion
Absorption by Ozone:
Although ozone is a minor component of the
atmosphere, it absorbs most UVB radiation.
Decreases in stratospheric ozone levels lead to
higher UVB reaching Earth’s surface.
Historical Data:
UV-driven phenolic formation in tree rings dates
ozone depletion in northern latitudes to the late
1700s.
A 2008 Ecuadorian Space Agency report found
unexpectedly high UV radiation levels in equatorial
latitudes, with UV Index reaching 24, compared to
WHO’s extreme risk level of 11. The findings were
confirmed by the Peruvian Space Agency.

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 10

Biological Effects
Main concerns include increased UV radiation's
impact on human health.
Ozone depletion typically shows a few percent
reduction in most locations, with no direct evidence
linking it to health damage at most latitudes.
Severe depletion, like the Antarctic ozone hole, has
led to concerns for Australia, New Zealand, Chile,
Argentina, and South Africa, possibly leading to
significant health effects.
Ozone depletion magnifies UV effects, both positive
(e.g., Vitamin D production) and negative (e.g.,
sunburn, skin cancer, cataracts).
Increased surface UV also boosts tropospheric
ozone, posing additional health risks

Effects on Crops
Increased UV radiation affects crops by harming
cyanobacteria on plant roots, crucial for nitrogen
retention.
Despite repair mechanisms, plants struggle to adapt
to increased UVB, impacting growth.
Global Warming and Climate Change:
Global warming refers to the century-scale rise in
Earth's average temperature and its effects.
Evidence shows unprecedented climate changes
since the 1950s.
IPCC 2014 Report:
Human influence is the dominant cause of warming
since mid-20th century, mainly due to greenhouse
gases (CO2, methane, N2O).
Climate models predict a further rise in global
surface temperature by 0.3 to 1.7 °C for the lowest
and 2.6 to 4.8 °C for the highest emissions scenarios.

©️Mahmoud Alaa
11 Pollution Microbiology 2024/2025

Future Impacts:
Warming temperatures, rising sea levels, changing
precipitation patterns, expanding deserts.
More extreme weather events: heat waves, droughts,
heavy rainfall, floods, snowfall.
Ocean acidification, species extinctions, threats to
food security, abandonment of populated areas.
Long-term Effects:
Climate changes will persist for tens of thousands of
years due to the longevity of greenhouse gases in the
atmosphere.
Societal Responses:
Mitigation (reducing emissions), adaptation,
resilience building, and potential climate engineering.
UNFCCC aims to prevent dangerous anthropogenic
climate change, with agreements to cut emissions
and limit global warming.
Public Concern:
Increasing global concern, with significant regional
differences. Americans and Chinese are among the
least concerned, despite their high CO2 emissions.

Global Warming & Greenhouse Gases
Pollutants contributing to global warming are called
greenhouse gases.
Major greenhouse gases: Carbon dioxide (CO2),
methane (CH4), nitrous oxide (N2O), and
chlorofluorocarbons (CFCs).
Greenhouse Effect:
Greenhouse gases trap heat in the atmosphere.

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 12

Main Greenhouse Gases:
Carbon dioxide (CO2): Primary greenhouse gas from
human activities, accounting for ~80.9% of emissions
in 2014. Naturally present in the Earth's carbon cycle
but increased due to human activities, particularly
from burning fossil fuels and certain industrial
processes.
Methane (CH4)
Nitrous oxide (N2O)
Ozone (O3)
Chlorofluorocarbons (CFCs)

Human Impact:
Human activities add more CO2 to the atmosphere
and influence natural sinks like forests.
Increased CO2 emissions since the industrial
revolution have disrupted the natural carbon cycle.

©️Mahmoud Alaa
13 Pollution Microbiology 2024/2025

Particulate Matter (PM)
Definition:
Microscopic solid or liquid matter suspended in the
atmosphere, known as particulate matter (PM) or
particulates. Aerosol refers to the particulate/air
mixture.
Sources:
Manmade or natural, impacting climate and human
health.
Subtypes:
Suspended particulate matter (SPM)
Thoracic and respirable particles
Inhalable coarse particles (2.5 to 10 µm in diameter,
PM10)
Fine particles (2.5 µm or less, PM2.5)
Ultrafine particles and soot
Health Risks:
Particulates are Group 1 carcinogens (IARC, WHO).
Deadliest air pollution type, penetrating deep into
lungs and bloodstream, causing DNA mutations,
heart attacks, and premature death.
2013 study: No safe level of particulates; 22% increase
in lung cancer risk per 10 µg/m³ of PM10, 36% for
PM2.5.
Natural Sources:
Volcanoes, dust storms, forest and grassland fires,
vegetation, sea spray.
Human Sources:
Burning fossil fuels in vehicles, power plants,
industrial processes.
Coal combustion in developing countries.
Size of Particulate:
Natural aerosols (e.g., dust) have larger radii than
human-produced aerosols (e.g., pollution).

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 14

Natural sea salt is the primary aerosol in the Southern
Hemisphere; land fires and human activities
dominate in the Northern Hemisphere.
Regional Patterns:
Southern Hemisphere: Large aerosols over oceans
(sea salt).
Northern Hemisphere: Small aerosols over land (fires,
human activities).
Dust storms prominent in deserts (Sahara, Arabian
Peninsula).
Fire activities (Amazon, Northern Canada) produce
smaller aerosols.
Human pollution creates small aerosols over
developed areas (eastern U.S., Europe).

©️Mahmoud Alaa
15 Pollution Microbiology 2024/2025

Effects of Air Pollution on Plants

Cardiovascular
Diseases

Respiratory
Diseases Habitat
Climate Damage
Premature Change
Death Food Source
Damage
Health Global
Impacts Impact Water
Acidification

Humans Animals

Air
Pollution

Plants

Fluoride
SO2 Damage O3 Damage
Damage

Sensitive Sensitive
Species Species

©️Mahmoud Alaa
Microbiology 2024/2025 Pollution 16

Effects of Particulate Matter on Vegetation and
Humans
Vegetation:
Impact: Particulate matter clogs stomatal openings,
hindering photosynthesis.
Result: High concentrations lead to growth stunting
or mortality in some plant species.
Humans:
Health Risks: Inhalation of particulate matter is linked
to asthma, lung cancer, cardiovascular disease,
respiratory diseases, premature delivery, birth
defects, and premature death.
Statistics:
PM pollution causes 22,000–52,000 deaths per
year in the U.S. (2000).
Contributed to ~370,000 premature deaths in
Europe (2005).
Caused 3.22 million deaths globally (2010).
Studies:
PM2.5 linked to high plaque deposits in arteries,
causing vascular inflammation and
atherosclerosis.
Long-term exposure to PM2.5 linked to coronary
events; a 5 µg/m³ increase correlates with a 13%
increased risk of heart attacks.
Black Carbon exposure impacts bacteria, altering
biofilm formation and antibiotic tolerance.
WHO Estimates (2005):
PM2.5 causes ~3% mortality from
cardiopulmonary disease.
~5% mortality from cancer of the trachea,
bronchus, and lung.
~1% mortality from acute respiratory infections in
children under 5.

©️Mahmoud Alaa