Environmental Sciences CIE 1072 Course Notes PDF

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This document is a course outline for a course called Environmental Sciences, CIE 1072. The notes cover various topics including concepts of environment, environmental sciences, renewable and nonrenewable energy sources, forests, and water resources.

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ENVIRONMENTAL SCIENCES
CIE – 1072
Course Instructor: Dr. Chythanya Krishnan
Concept of Environment
 Environmental Sciences as a multidisciplinary approach
Life Sciences Physical Sciences
Biology Chemistry
Biochemistry Physics
Microbiology Earth Science
Biotechnology Environmental Atmospheric Science
Oceanography
Engineering Sciences Geography
Civil
Chemical Maths
Hydraulics Economics
Statistics Sociology
Mechanical Data Science Law
Demography Education
Computer science Mass communication
Management
Local nature of Environment
❖ Impact of mining on a locality
❖ Disposal and management of solid waste issues
❖ Impacts of hydro-electric / nuclear / thermal power
plant in a community
❖ Arsenic / lead /heavy metal pollution of groundwater
storage
❖ Water logging and salinization of soil
❖ River or lake pollution from nearby industry or human
dwellings
❖ Soil erosion
❖ Wildfires
❖ Landslides
❖ Droughts / Floods
❖ Deforestation
❖ Impact of fertilizer / pesticide on the local residents
near the agricultural field
Individual Nature of environment
Clean air, water and fertile land
Hygienic living conditions
Healthy and sustainable food
Food security

Public Awareness - Government bodies alone cannot bring
about conservation practices without public participation.
Public awareness – address the environmental issues within
various sectors of public.
Campaigns, Non government Organizations (NGO), College
Eco-clubs, social media and posters etc.. Means of awareness.
Renewable energy sources are replenished naturally and can be utilized indefinitely
because their supply is essentially infinite. These sources are considered sustainable
and environmentally favorable.

a. Solar Energy: Solar panels generate electricity from sunlight.

b. Wind Energy: Wind turbines generate electricity by harnessing the kinetic energy
of the wind.

c. Hydropower: The passage of water through dams or other water infrastructure
generates energy.

d. Biomass: To generate energy, organic materials such as biomass, agricultural
residues, and refuse are burnt or converted into biofuels.

e. Geothermal Energy: Earth's internal heat is used to generate electricity or heat
structures.

f. Forest resources: wildlife - flora and fauna provides numerous ecological, medicinal
and economic uses.
Nonrenewable energy sources are limited and will deplete over time. They will not
get replenished if extracted exponentially by humans. Their combustion releases
greenhouse as well as other toxic gases leading to a negative impact to the
environment.
a. Fossil Fuels: Coal, oil, and natural gas fall under
this category. They are composed of the remains
of extinct vegetation and animals and, when
incinerated, emit carbon dioxide and other
contaminants. They are the primary energy
sources in many regions of the globe.

b. Nuclear Energy: Nuclear energy is generated
through nuclear fission. Although it does not
produce greenhouse gas emissions, there are
hazards associated with nuclear waste and
accidents.
Major concerns with Non-Renewable energy Sources and their
generation:
1. Greenhouse gas emissions
2. Land and soil degradation -owing to mining of these resources
3. Air pollution from their combustion
4. Waste Disposal
5. Oil Spillage
6. Vicinity to human settlements
7. Accidents
8. Acid rain
9. Health hazards
Sustainability, environmental impact, and availability are
the main distinctions between renewable and
nonrenewable energy sources. Renewable sources are
more sustainable and have a lower environmental impact
than nonrenewable sources, which are limited and have a
greater environmental impact.

Due to concerns about climate change, pollution, and
resource depletion, the transition from non-renewable to
renewable energy sources is a global priority. It is
believed that increasing the use of renewable energy can
mitigate/reduce these issues.
 Forest Resources : For both human well-being and the
welfare of our planet, forests provide a vast array of
valuable resources. Here are several of the most important
applications of forest resources:

Forests are a significant supplier
of timber and natural products.
For construction materials,
furniture, paper, and other
wood-based products, trees are
harvested.
 Non-Timber Forest Products (NTFPs): Non-timber forest products include seeds,
fruits, fungi, medicinal plants, resins, and natural pigments.

Conservation of Biodiversity: Forests are home to an extensive number of animal
and plant species.

Water Resources: Watershed forests regulate water volume and quality. They
reduce erosion, filter pollutants, and maintain potable, irrigation, and industrial
water supplies.

Forests perform an essential function in sequestering carbon dioxide from the
atmosphere, thereby mitigating climate change. They function as carbon sinks by
storing carbon in their trees and soils for extended periods of time.

Forests provide numerous opportunities for recreation and tourism, such as
hiking, camping, birdwatching, and ecotourism. This leads to economic benefits
for local communities.
 Ecosystem Services: Forests provide essential habitat for numerous species and a
variety of ecosystem services, such as pollination, insect control, and nutrient
cycling.

Bioenergy: Wood and plant materials from forests can be utilized as biofuels and
biomass for energy production, thereby reducing dependence on fossil fuels.

Numerous indigenous and traditional communities obtain medicinal flora and
botanical remedies from forest resources. Forests are a rich source of medicinal
plants.

Cultural and Spiritual Significance Forests are culturally and spiritually significant to
numerous communities across the globe. They serve as sites for rituals, ceremonies,
and traditional practises frequently.

Hunting and Fishing: Forests provide opportunities for hunting and fishing, which can
be essential to survival in some regions.
 For scientific inquiry and environmental education, forests are essential. They
offer the chance to investigate ecosystems, fauna, and the influence of humans on
the environment.

Conservation of Forest resources is crucial for the present and future generations
as well. Sustainable forest management strives to balance between the rate of
resource extraction and conservation practices.
Deforestation - process of clearing or removing forests or trees from a
particular area: mainly for human activities.

Environmental Effects of Deforestation:

Loss of Biodiversity: One of the most immediate and critical consequences of
deforestation is the loss of biodiversity and may leads to their extinction.

Climate Change: Forests act as carbon sinks, absorbing and storing large
amounts of carbon dioxide. When forests are cleared or burned, this stored
carbon is released into the atmosphere, contributing to global greenhouse gas
emissions and climate change.

Disruption of Water Cycles: Forests play a crucial role in regulating water
cycles. They absorb rainfall, reduce runoff, and release water gradually, helping
to prevent floods and droughts. Deforestation can disrupt these cycles, leading
to water quality and quantity issues.
 Soil Erosion: Tree roots help anchor soil, preventing erosion. When
forests are removed, especially on steep slopes, soil erosion becomes
a significant problem, degrading the quality of soil and causing
sedimentation in nearby water bodies.

Loss of Medicinal Plants: Many medicinal plants are found in forests,
and their loss due to deforestation can have consequences for
traditional medicine practices and pharmaceutical research.
Social and Economic Effects of Deforestation:

Displacement of Indigenous Peoples: Indigenous communities often
rely on forests for their livelihoods, culture, and traditional
knowledge. Deforestation can lead to the forced displacement of
these communities, often with serious consequences for their well-
being.

Loss of Livelihoods: Many people depend on forests for their
livelihoods, including those engaged in forestry, agriculture, and the
collection of non-timber forest products. Deforestation can lead to
job losses and economic hardships for local residents.

Deforestation can lead to changes in local climates like factors like
altered rainfall patterns, soil degradation, and increased pest
problems.
 Overgrazing – local
Raw Materials for
people may only
Industrial use –
afford to graze their
Fuel Requirements- and tea plantation
livestock in the woods
Exponential land requirements
demand for fuel
wood Causes of
Deforestation Mining Activities
Shifting
agriculture – people
clear forest and Growing food needs
does farming and Developmental – extensive
leave the land Projects agriculture / cash
hydroelectric crops in the forest
projects (Dams). area
Wildfire /Forest Tunnels,Road
fires construction
 Water Resources – Renewable

Source :https://www.researchgate.net/figure/Distribution-of-
Earths-water-Reference-2_fig1_332910952
 Negative Impacts
✓ Deforestation and loss of
Impacts of Big Biodiversity
Dams ✓ Water Logging and salinity
✓ Flash floods
✓ Change in water flow and
siltation
✓ Reservoir induces Seismicity
✓ Submergence of village and
Positive Impacts fertile lands
Prevention of Floods ✓ Displacement of local
Employment residents
Electricity Generation ✓ Resettlement issues
Irrigation water supply ✓ Outbreak of vector borne
Drinking water supply diseases - Malaria, Dengue
Promotion of Navigation
Promotion of Tourism,
Promotion of Fisheries
 The hydrological-cycle

Source: https://civilsolution.wordpress.com/2013/02/06/the-hydrological-cycle/
The Hydrological Cycle

Base flow
Source:
https://link.springer.com/referenc
eworkentry/10.1007/978-3-319-
39312-4_158
The hydrological cycle / water cycle is the mechanism by which water moves
from the Earth's surface to the atmosphere and then returns to the ground.
The sun facilitates a continuous transfer of moisture between the seas, land,
and atmosphere by supplying energy.

Hydrology is the science that encompasses the occurrence, distribution,
movement and properties of the waters of the earth and their relationship
with the environment within each phase of the hydrological cycle.

The various processes involved in the hydrological cycle are;
1. Evaporation
2. Transpiration
3. Condensation
4. Precipitation
5. Interception
6. Run-off
7. Infiltration
8. Percolation
9. Base Flow
1.Evaporation :Evaporation is the process by which water transitions from a liquid state
to a gaseous one. The quantity of natural evaporation in any geographic location is
primarily influenced by solar radiation, as well as other elements like air temperature,
vapour pressure, wind, and atmospheric pressure. Evaporated moisture is lifted into the
atmosphere from the ocean, land surfaces, and waterbodies as water vapour.

2. Transpiration is the process by which moisture is carried through plants from roots to
small pores on the underside of leaves (stomata) , where it changes to vapor and is
released to the atmosphere. Normally, transpiration through stomata and evaporation
from the surface of the leaves occurs simultaneously thereby referring as evapo-
transpiration from trees or plants.

3. Condensation : Condensation is the process by which water vapor changes it's physical
state from a vapor, most commonly, to a liquid. Water vapor condenses onto small
airborne particles to form dew, fog, or clouds. The most active particles that form clouds
are sea salts, atmospheric ions caused by lightning, and combustion products containing
sulfurous and nitrous acids. Condensation is brought about by cooling of the air or by
increasing the amount of vapor in the air to its saturation point
4. Precipitation : Precipitation is the process that occurs when any and all forms of
water particles fall from the atmosphere and reach the ground. There are two sub-
processes that cause clouds to release precipitation, the collide-coalescence
process and the ice- crystal process.
5. Interception :Rainfall interception is the fraction of rain that falls onto
vegetation but never reaches the ground, instead evaporating from the wet canopy.
Interception is significant in forest as the forest canopy intercepts the
precipitation / rainfall and moderate the local hydrology. Large-scale Deforestation
thus affects this part of hydrological cycle.

6. Surface Runoff : Runoff occurs when there is
excessive precipitation and the ground is
saturated (cannot absorb any more water). The
water flows over land and reaches rivers, lakes or
oceans. Some runoff evaporates into the
atmosphere.
7. Infiltration refers to the movement of water from the Earth's surface into the soil-
surface. The process of infiltration holds significance in several areas such as irrigation,
pollutant migration, groundwater replenishment, and ecosystem sustainability.

8. Percolation is the vertical movement of water through the soil itself to the deeper
sub-surface layers /rocks. Percolation of rainfall leads to groundwater storage.

9. Base Flow: The lateral movement of groundwater within the sub-surface and joining the
sea / water bodies

https://rainfalltogroundwater.net/water-yield-vs-baseflow-augmentation/
 While water vapour condenses to form dew drops or frost/ice, the
below two mechanisms occurs:
1. Collision-coalescence process
2. Ice-crystallization process

1. Collision-coalescence process
Large Collector drops collide with smaller drops.
When collisions occur, drops either bounce apart or coalesce into one
larger drop.
Collision and coalescence together form the primary mechanism for
precipitation in the tropics, where warm clouds dominate.
2. Ice-crystallization process

Cold clouds are referred to those have temperature
below freezing point or 0ºC throughout and consist
entirely of ice crystals, supercooled droplets, or a
mixture of two.
Supercooled water and ice crystals grow to form larger
ice crystals – the process is called Bergeron process or
ice-crystallization process.
 Ice Crystallization /

Source: https://geography4u.com/types-of-precipitation-and-rainfall/
Aquifer: An aquifer is a porous, water-saturated
layer of sand, gravel, or bedrock, which contains
groundwater or has flowing groundwater. A
geological formation in the earth that holds and
transmits water. Aquifer is a saturated formation
as all the pores are filled with water.

Top soil is an Unsaturated zone – where both air
and water are filled between pores. Thus it is not
an aquifer and do not provide groundwater when
pits are dug in the top soil.
❖ Unconfined Aquifers
Where groundwater is in direct contact with the atmosphere through the
open pore spaces of the overlying soil or rock, then the aquifer is said to be
unconfined. The upper groundwater surface in an unconfined aquifer is called
the water table and is open to atmospheric pressure. The depth to the water
table varies according to factors such as the topography, geology, season and
tidal effects, and the quantities of water being pumped from the aquifer.

Unconfined aquifers are usually recharged by rain or streamwater infiltrating
directly through the overlying soil. Typical examples of unconfined aquifers
include many areas of coastal sands and alluvial deposits in river valleys.
Confined aquifers are permeable rock units that are usually deeper under the
ground than unconfined aquifers. They are overlain by relatively impermeable
rock or clay that limits groundwater movement into, or out of, the confined
aquifer.
Groundwater in a confined aquifer is under pressure and will rise up inside a
borehole drilled into the aquifer. An artesian flow is where water flows out
of the borehole under natural pressure.
Confined aquifers may be replenished, or recharged by rain or streamwater
infilitrating the rock at some considerable distance away from the confined
aquifer. Groundwater in these aquifers can sometimes be thousands of years
old.

Aquiclude – Aquiclude- geologic formation which may
contain water, but is incapable of transmitting water.
Example : Clay, granite, marble
Source: https://www.researchgate.net/figure/Figure-A-2-Cross-section-sketch-of-a-typical-
ground-water-flow-system-showing-the_fig1_255948122

Source: https://theconstructor.org/geotechnical/types-geological-formations-
groundwater/34672/
 Mineral Resources
A mineral is a natural inorganic solid with a specific
internal structure, a chemical composition and
characteristic physical properties.

Minerals and metals finds applications as follows:
1. Development of industrial plants and machinery
2. Generation of energy e.g., coal, lignite, uranium
3. Construction, housing, settlements,
4. Defense equipment – weapons, armaments
5. Transportation means
6. Communication - telephone wires, cables, electronics Source :https://ohiodnr.gov/discover-and-learn/rock-
minerals-fossils/minerals
devices
7. Medicinal system – particularly in Ayurvedic system
8. Formation of alloys e.g., steel alloys
9. Agriculture as fertilizers, equipments.
10.Jewelry – gold, silver, diamond, platinum
Source: https://www.neetprep.com/ncert/1605-General-Principles-Processes-Isolation-Elements-General-
Principles-Processes-Isolation-Elements--NCERT-Chapter-PDF
Critical minerals - required for Strategic minerals – required for
economy defense
Iron, Aluminum, Copper, Gold, Silver Manganese, Cobalt, Platinum, Chromium
Mining – extraction of minerals and fossil
fuels.
Deep deposits – sub-surface mining
Shallow deposits – surface mining
1. Open pit mining – machines dig holes and
remove the ores – for minerals like
copper, iron, limestone, sandstone,
marble, granite
2. Dredging – chained buckets and
draglines extract underwater minerals –
sand and for minerals in aqueous solution
like gold.
3. Strip mining – ore is stripped off by
Open pit mining
using bulldozers, power shovels,
stripping wheels - for phosphate rocks

Source: https://www.shutterstock.com/search/strip-mining
 Dredging Mining

Strip mining

Source: https://www.shutterstock.com/search/strip-mining
 Mining accident due to landslide in China
Source
:https://news.rthk.hk/rthk/en/compon
ent/k2/1689056-20230222.htm
Source :https://insideclimatenews.org/news/15032022/coal-mining-
methane/.

A deep coal mine
Ecological Impacts of Mining
1. Devegetation and defacing of landscape – The topsoil as well as vegetation are
removed from the mining area to get access to the deposit. While large scale
deforestation leads to landslides and soil erosion, the landscape is also deeply
affected. The debris and tailings along with big scars(marks due to movement and pit)
and disruptions spoil the aesthetic value of the region and make it prone to soil
erosion.
2. Subsidence of land: This is mainly associated with underground mining. Subsidence of
mining areas often results in tilting of buildings, cracks in houses, buckling of roads,
bending of tail racks and leaking of gas from cracked pipe-lines leading to serious
disasters.
3. Groundwater Contamination – Impurities such as Sulphur gets converted to sulphuric
acid through microbial action making water acidic. Also, heavy metals leach into the
soil thereby contaminating the groundwater storage.
4. Surface water pollution – The acidic water along with wastes from mines may contain
metals like Uranium, Mercury which gets carried away into the nearby streams or
rivers. These poses detrimental effects to aquatic life in the nearby streams / rivers
and makes water unfit for drinking and human consumption.
5. Air pollution – Metals are separated and sometimes purified in the mining
sites itself. During this process enormous quantities of air pollutants mainly
dust, aerosols, soot, arsenic particles, cadmium, lead, Sulphur Oxides,
Suspended particulate matter (SPM), gets released in the mining site causing air
pollution.
6. Loss of flora nd fauna – Plant and animal population gets adversely affected
due to massive deforestation and landscape disruptions resulting in loss of
biodiversity. And ecosystem degradation.
7.Noise pollution – Dynamite blasting and deep mining excavation results in loud
noises and disturbances to daily life of the people in the surrounding locality.
8.Soil pollution – revegetation, leaching of unwanted mining wastes results in
loss of soil fertility and its natural characteristics leading to soil contamination.
Socio-economic Impacts from mining
1. Encroachment and evacuation – Due to possibility of the accidents or sinking
of the land, people have to displaced in and around the mining area. Mining can
encroach on the lands of indigenous communities, leading to land rights
disputes and cultural impacts.

2. Rehabilitation and resettlements –People who have been made to move
cannot fully recover and improve their income and living standards just by
getting paid more compensation buy concerned authorities.

3. Depletion of Resources: Several extracted resources, such as fossil fuels
and certain metals, have a limited supply and cannot be replenished. Excessive
exploitation may result in the exhaustion of resources.
4. Human Rights and Social Concerns : Labor Conditions: Miners often work in
challenging and sometimes hazardous conditions. Issues like worker safety, fair
wages, and labor rights are concerns in many mining regions.

5. Occupational health hazards - Exposure to mining-related pollutants, including
dust and chemicals, can pose health risks to both miners and nearby
communities. Miners are at risk of developing a lung disease called
pneumoconiosis because of their exposure to airborne respirable dust. Health
hazards like Asbestosis, Silicosis Occupational cardiovascular diseases, Lead
toxicity, Neurotoxic disorders, Noise-induced hearing loss, Dermatologic
conditions, Psychological disorders, Severe occupational traumatic injuries, etc..
also exists

6. Transparency and Accountability:
Some mining operations lack transparency, making it difficult to track
environmental and social impacts or hold companies accountable for their actions.
7. Accidents- Mining accidents can have devastating consequences for both workers and the
environment.
Explosions: Mining operations involving flammable gases (e.g., methane in coal mines) can lead
to explosions. These explosions are often caused by ignition sources like electrical equipment
or sparks from machinery.
Roof and Rib Falls: In underground mines, the collapse of the roof or ribs (the sides of the
mine) is a significant hazard. This can happen due to weak geological conditions, inadequate
roof support, or improper mining methods.
Fires: Fires in mines can result from various sources, including electrical faults, equipment
overheating, or the combustion of flammable materials. The confined and often inaccessible
nature of underground mines makes firefighting challenging.
Haulage Accidents: Accidents involving the transportation of materials, machinery, or
personnel in and out of mines can result from equipment malfunctions, operator error, or
inadequate safety measures.
Falls: Slips, trips, and falls are common accidents in mining operations. These can occur on
uneven terrain, ladders, scaffolding, or during the operation of heavy machinery.
Equipment Accidents: Malfunctions or improper use of heavy mining equipment and machinery
can lead to accidents, including crushing injuries, collisions, and equipment rollovers.
Tunnel and Shaft Collapses: The structural integrity of tunnels and shafts is crucial to
prevent collapses, which can be deadly for miners working underground.
 1.Agriculture and Food Resources
Agriculture is the science or practice of farming, including the
cultivation of the soil for crop production and the nurturing of
livestock for food, fiber and other products.
Food security is achieved via agriculture, which is the major source of food
production. A stable and productive agricultural sector is critical for guaranteeing
global food security, eliminating hunger, and avoiding food shortages, especially in
vulnerable areas.

Nutrition and Health: Agriculture provides a varied variety of nutrients required for
human health in addition to calories. A varied diet rich in fruits, vegetables, grains,
and animal products improves general nutrition and well-being.

Agriculture contributes significantly to global economic growth. It employs a sizable
section of the global population and provides a source of income for millions of
individuals, particularly in developing nations. Agriculture provides a source of income
and may help fuel economic development and poverty alleviation.
Agriculture is a source of food energy, but it is also a source of bioenergy. Crops such as
maize, sugarcane, and oilseeds are utilised to make biofuels, which may be used instead of
fossil fuels. This improves energy security while also lowering greenhouse gas emissions.

Agriculture is the backbone of many rural communities, and its success is inextricably linked
to the well-being of these communities. A flourishing agriculture industry may aid rural
development by creating employment and infrastructure.

Cultural and Social Significance: Agriculture is deeply rooted in the culture and traditions of
many societies. It plays a crucial role in shaping identity, heritage, and social structures in
rural areas.

Global Trade: Agriculture and food are international commodities, and global trade in
agricultural products is essential for supplying regions with what they cannot produce
themselves. This global trade is vital for ensuring a variety of food products year-round.
https://geopoliticalfutures.com/food-insecurity-outlook-for-2023/
The food gap between advanced and developing economies is growing. Developed
countries tend to have stronger currencies and better access to credit, meaning
food supplies and input materials are generally more affordable and accessible than
in developing economies. The most vulnerable countries, however, are often forced
to work with institutions like the International Monetary Fund to secure financing
to pay for imports.

Countries that rely on food imports and have
low foreign reserves are at greatest risk of
seeing a lack of access to food. Costly
agricultural input materials, labor and energy
also contribute to high food costs.

https://www.smilefoundationindia.org/blog/are-philanthropic-efforts-sufficient-to-curb-issues-
such-as-world-hunger/
 Impacts of Overgrazing and Agriculture
Impacts of Overgrazing : Livestock plays a crucial role in rural life. The huge population
of livestock needs to be fed and the demand for grazing lands rises. Overgrazing occurs
when livestock feeds on grasslands or pasture ;lands beyond the carrying capacity or
renewal capacity of such lands. Impacts of overgrazing are:
1. Land Degradation – Overgrazing removes the vegetal cover over the soil resulting in
reduced fertility, poor dry and compacted soil. Also continuous movement of livestock
results in compaction of soil –causing blockage to rain water percolation to deeper soil
layers.

2. Soil erosion –Grasses and plants hold top soil through their roots. Due to overgrazing
by cattle and other livestock, the cover of

3. Loss of useful species – Plant population gets adversely affected by overgrazing and
unscientific grazing methods. Indigenous plant of useful value may get replaced by
thorny plants or weeds. Example: As a result of overgrazing in vast areas in Arunachal
Pradesh and Meghalaya in India are getting invaded by thorny bushes weeds etc.. of low
nutritional values.
 Impacts of Agriculture

It usually employs small tools, pot,
Traditional
naturally available water, organic
Agriculture
fertilizers
It makes use of hybrid high yielding
Modern seeds and plat varieties, fertilizers,
agriculture high-tech equipments, pesticides,
irrigation water
 Impacts of Traditional Agriculture

Deforestation – Traditional farming usually clears a part of forest and burn.
The crops are grown in the burnt land. The land is left and new forest cover is
cleared for next farming season. This method is called slash and burn or
shifting cultivation. This results in deforestation.

Soil Erosion – Clearing of forest cover for traditional agriculture
results in floods, erosion due to strong winds or heavy rainfall.

Depletion of nutrients – During shifting cultivation, the land loses its fertility
due to nutrient intake by crops grown. This cultivated land is left untreated
without any fertilizer treatment resulting in loss of fertility. The farmers shift
their farming to a new land by clearing forest.
Impacts of modern Agriculture

Impacts from High Yielding variety of plants

Impacts from Fertilizers

Impacts from Pesticides

Water logging problems

Salinity Problems
 1. Impacts from High Yielding variety of plants : The use of high yielding
variety of crops result in monoculture –only that crop is grown in vast
areas. Any attack from pests or pathogen on this variety will result in crop
destruction over vast areas leading to economic loss and food insecurity
issues. Also preference to genetically modified and hybrid crop variety will
cause reduced preference for cropping of local indigenous variety of the
same crop.
 1. Impacts from Fertilizers

a. Micronutrient imbalance - Most of the chemical fertilizers used in modern agriculture have nitrogen,
Phosphorous and Potassium which are essential macronutrients. Farmers use excessive fertilizers to
boost crop growth. High amounts of such nutrients result in imbalance to micronutrients like Zinc.
Example is Punjab and Haryana.

b. Nitrate Pollution – Nitrogenous fertilizers applied in the fields often leach deep down into the
groundwater causing its pollution. The nitrates concentrated in the water if exceeds 25mg/liter, causes
health hazard called Blue baby syndrome causing infant deaths. This problem is very prevalent in
Denmark, England, France and Netherlands. In India also this exists.

c. Eutrophication – Excessive use of nitrogen and phosphorous gets washed off to nearby water bodies.
These nutrients nourishes the water bodies and causes fast growth of algae rapidly. The algal species rapidly
flourish over the water surface consuming Oxygen in the process. Also sunlight is prevented from reaching
the water body depths due to algal bloom over the surface – the condition called Eutrophication. This results
in devastation of the aquatic ecosystem and deaths of fish species.
3. Impacts from Pesticides – Thousands of pesticides are used in agricultures such
as Sulphur, arsenic, lead , mercury and DDT

a. Resistance to pesticides and super pests – Over the years the pests become resistant to
pesticides. Over 20 species of pests are known to resistant to variety of pesticides. They are
called” Super Pests”.

b. Death of non-target organisms – Many pesticides kills non target organisms which are not
pests to crops, example –honeybees, butterflies.

c. Biomagnification – Many pesticides are non-biodegradable and keep accumulating in the
food chain , process called biomagnification. Since humans belong to the highest level in the
food chain, they get the pesticides accumulated in their bodies.
 4. Water logging problems – Over-irrigation of the farmlands by farmers for good crop
growth leads to water logging. Inadequate drainage in such areas results in increased water
accumulation in the groundwater storage and water table rises resulting in loose soil and
crop yield reduces. Example: In Punjab and Haryana –excessive canal irrigation led to
water-logging problems.

5. Salinity Problems – Excessive fertilizers and irrigation leads to increased soil
salinity. Salts such as sodium chloride, sodium sulphide calcium chloride,
magnesium chloride are found in high amounts in irrigated areas of the world.
Increased salinity results in pH imbalance of soil. Irrigation water unlike rainwater is
not pure and contains salts. Not all the salts are taken up by the plants. When the
irrigated water dries out the salts remain in the soil.