Earth Materials and Resources PDF

Summary

This document presents a comprehensive overview of Earth materials and resources. It covers topics such as minerals, rocks, energy, water, and soil resources, their properties, and the significant roles they play in various processes and modern life.

Full Transcript

GROUP 1 PRESENTS
EARTH
MATERIALS AND RESOURCES
The Earth's
surface is
constantly
changing.
 The Earth's surface
is always changing
TRUE because of things
like wind, water,
and even other
natural
events. Sometimes, mountains
grow taller, and other times, rivers
make new paths, showing that our
planet is always busy and never
stays the same for too long.
Earthquakes can happen
very quickly.
 During an
TRUE earthquake,
the ground
shakes and
moves suddenly causing
buildings to sway and crack,
and sometimes even
changing the shape of the
land, like hills or mountains,
in just a short amount of
time.
A gradual change is a
slow transformation
that occurs over a
period of time.
 A gradual change or
process occurs in
TRUE small stages over a
long period of time,
rather than
suddenly.
 Earth's materials
deteriorate and gets
recycled.
 Earth’s each
different material
TRUE
can get deteriorate.
While in the process
of it, other geo
matter can be
Recycled by introducing new
mixes and compounds that
reforms into the current
geological matter.
An avalanche is an example of a
slow change to Earth's surface.
 An avalanche is a
rapid and sudden
FALSE change to the
Earth's surface,
where a large
amount of snow or ice slides
down a slope, covering the
land and altering the shape of
the terrain in a matter of
seconds or minutes.
 Sand
dunes are
created
rapidly.
 Sand dunes are a
slow change to the
FALSE
Earth's surface,
formed over a long
period of time as wind gradually
moves and accumulates sand
particles, shaping them into
distinctive dune formations.
 Tsunamis are a
fast change to the
Earth's surface.
 Tsunamis are
TRUE a fast change
to the Earth's
surface. They
occur when there is a sudden
displacement of water,
usually caused by underwater
earthquakes or volcanic
eruptions, resulting in a series
of powerful ocean waves that
cancause significant damage.
Minerals and Rocks
FUNDAMENTAL COMPONENTS OF
THE EARTH’S CRUST.

A MINERAL IS A NATURALLY
OCCURRING, INORGANIC SOLID
THAT POSSESSES A DEFINITE
CHEMICAL COMPOSITION AND A
CRYSTALLINE STRUCTURE.

THESE MINERALS ARE THE BUILDING
BLOCKS OF ROCKS AND ARE FOUND
IN VARIOUS ENVIRONMENTS,
FROM THE EARTH'S SURFACE TO
DEEP WITHIN ITS CRUST.
Classification
of
Minerals
MINERALS ARE CLASSIFIED INTO VARIOUS GROUPS BASED ON
THEIR CHEMICAL COMPOSITION AND CRYSTAL STRUCTURE, WITH
THE MOST SIGNIFICANT DISTINCTION BEING BETWEEN SILICATE
AND NON-SILICATE MINERALS. SILICATE MINERALS, WHICH
INCLUDE QUARTZ, FELDSPAR, AND MICA, ARE THE MOST
ABUNDANT GROUP, COMPRISING ABOUT 90% OF THE EARTH'S
CRUST.

Silicate Minerals Non-Silicate Minerals
 NON-SILICATE MINERALS ARE A DIVERSE GROUP THAT INCLUDES SEVERAL
SUBCLASSES, EACH WITH UNIQUE CHARACTERISTICS. CARBONATES (E.G.,
CALCITE) CONTAIN THE CARBONATE ION (CO₃²⁻) AND ARE COMMONLY
FOUND IN SEDIMENTARY ROCKS LIKE LIMESTONE. OXIDES (E.G.,
HEMATITE) CONSIST OF OXYGEN AND ONE OR MORE METALS AND ARE
IMPORTANT ORES FOR EXTRACTING METALS LIKE IRON. SULFATES (E.G.,
GYPSUM) CONTAIN THE SULFATE ION (SO₄²⁻) AND ARE OFTEN FORMED IN
EVAPORATIVE ENVIRONMENTS.

Silicate Minerals Non-Silicate Minerals
 HALIDES (E.G., HALITE) ARE COMPOSED OF A HALOGEN ION COMBINED
WITH ANOTHER ELEMENT, TYPICALLY FORMING IN SALINE
ENVIRONMENTS. SULFIDES (E.G., PYRITE) CONSIST OF SULFUR AND
METALS, COMMONLY FOUND IN HYDROTHERMAL DEPOSITS. FINALLY,
NATIVE ELEMENTS LIKE GOLD AND SILVER CONSIST OF A SINGLE ELEMENT
AND ARE HIGHLY VALUED FOR THEIR RARITY AND PURITY. THIS
CLASSIFICATION HELPS GEOLOGISTS AND MINERALOGISTS IDENTIFY AND
STUDY MINERALS BASED ON THEIR PROPERTIES AND FORMATION
ENVIRONMENTS.

Silicate Minerals Non-Silicate Minerals
Silicates or Non-silicates
 COLOR
Properties of Minerals:
HARDNESS
LUSTER: HOW A MINERAL REFLECTS LIGHT.
STREAK: REFERS TO THE COLOR OF A MINERAL IN ITS POWDERED FORM.
CLEAVAGE AND FRACTURE: HOW A MINERAL BREAKS.
SPECIFIC GRAVITY IS THE DENSITY OF A MINERAL RELATIVE TO THE
DENSITY OF WATER.
Formation and Types of
Minerals and Rocks
IGNEOUS ROCK
SEDIMENTARY ROCK
METAMORPHIC ROCK
Mineral Resources
MINERAL RESOURCES ARE
NATURALLY OCCURRING
CONCENTRATIONS OF MINERALS IN
THE EARTH’S CRUST THAT CAN BE
EXTRACTED AND PROCESSED FOR
HUMAN USE.

THESE RESOURCES ARE CRITICAL FOR
VARIOUS INDUSTRIES AND ARE
ESSENTIAL TO MODERN LIFE.
Types of Mineral Resources
 Classification:

METALLIC
NON-METALLIC
ENERGY MINERALS

Non-Metallic Minerals Metallic and Energy Mineral
 1. METALLIC MINERALS
Types of Soil
CONTAIN METAL ELEMENTS THAT
CAN BE EXTRACTED THROUGH
MINING AND REFINING.
EXAMPLES INCLUDE IRON,
COPPER, GOLD, AND ALUMINUM.
 1. METALLIC MINERALS

IRON - THE MOST COMMONLY USED METAL, ESSENTIAL IN STEEL
PRODUCTION. FOUND IN ORES LIKE HEMATITE AND MAGNETITE.

COPPER - WIDELY USED IN ELECTRICAL WIRING, PLUMBING AND
COINAGE. EXTRACTED FROM ORES LIKE CHALCOPRITE AND BORNITE.

GOLD - HIGHLY VALUED FOR IT’S RARITY AND CONDUCTIVITY. USED
IN ELECTRONICS, JEWELRY AND AS FINANCIAL STANDARD. FOUND IN
ORES LIKE QUARTZ VEINS AND PLACER DEPOSITS.

ALUMINUM - LIGHTWEIGHT, CORROSION-RESISTANT METAL USED
IN TRANSPORTATION, PACKAGING AND CONSTRUCTION. EXTRACTED
FROM BAUXITE ORE.
 2. NON-METALLIC MINERALS
Types of Soil
DO NOT CONTAIN METALS AND
ARE USED IN THEIR NATURAL
STATE. EXAMPLES INCLUDE
LIMESTONE, SAND, GRAVEL, AND
CLAY.
 2. NON-METALLIC MINERALS

LIMESTONE - USED IN THE PRODUCTION OF CEMENT, AS A BUILDING
STONE, AND IN THE PURIFICATION OF IRON. FOUND IN
SEDIMENTARY DEPOSITS.

SAND AND GRAVEL - ESSENTIAL FOR CONSTRUCTION, USED IN
CONCRETE, ROAD CONSTRUCTION AND LANDSCAPING.

CLAY - USED IN CERAMICS, BRICKS, AND AS A FILTER IN VARIOUS
PRODUCTS. FOUND IN SEDIMENTARY BASINS.

PHOSPHATE - USED IN FERTILIZERS TO ENHANCE SOIL FERTILITY.
EXTRACTED FROM SEDIMENTARY DEPOSITS
 3. ENERGY MINERALS
Types of Soil
INCLUDES RESOURCES USED
FOR ENERGY PRODUCTION,
SUCH AS COAL, URANIUM, AND
PETROLEUM-RELATED
MINERALS.
 3. ENERGY MINERALS

LIMESTONE - USED IN THE PRODUCTION OF CEMENT, AS A
BUILDING STONE, AND IN THE PURIFICATION OF IRON. FOUND IN
SEDIMENTARY DEPOSITS.

SAND AND GRAVEL - ESSENTIAL FOR CONSTRUCTION, USED IN
CONCRETE, ROAD CONSTRUCTION AND LANDSCAPING.

CLAY - USED IN CERAMICS, BRICKS, AND AS A FILTER IN VARIOUS
PRODUCTS. FOUND IN SEDIMENTARY BASINS.

PHOSPHATE - USED IN FERTILIZERS TO ENHANCE SOIL FERTILITY.
EXTRACTED FROM SEDIMENTARY DEPOSITS
 PROPERTIES OF A MINERAL:
COLOR
HARDNESS
LUSTER: HOW A MINERAL REFLECTS LIGHT.
STREAK: REFERS TO THE COLOR OF A MINERAL IN ITS POWDERED
FORM.
CLEAVAGE AND FRACTURE: HOW A MINERAL BREAKS.
SPECIFIC GRAVITY IS THE DENSITY OF A MINERAL RELATIVE TO THE
DENSITY OF WATER.
 Importance
ECONOMIC DEVELOPMENT: MINERAL
RESOURCES ARE A KEY DRIVER OF
ECONOMIC GROWTH, PROVIDING
RAW MATERIALS FOR
CONSTRUCTION, MANUFACTURING,
AND ENERGY PRODUCTION.

TECHNOLOGICAL ADVANCEMENT:
MANY MODERN TECHNOLOGIES,
FROM SMARTPHONES TO RENEWABLE
ENERGY SYSTEMS, RELY ON SPECIFIC
MINERALS.
Process of Extracting
Mineral Resources
 Process:
1. MINING METHODS:
SURFACE MINING: INCLUDES OPEN-PIT
MINING, STRIP MINING, AND
QUARRYING. IT INVOLVES THE REMOVAL
OF SURFACE VEGETATION, SOIL, AND ROCK
TO ACCESS MINERAL DEPOSITS.
UNDERGROUND MINING: INVOLVES
DIGGING TUNNELS OR SHAFTS TO REACH
DEEPER MINERAL DEPOSITS. IT IS USED
WHEN MINERALS ARE LOCATED TOO DEEP
FOR SURFACE MINING.
PLACER MINING: INVOLVES EXTRACTING
VALUABLE MINERALS FROM STREAM
SEDIMENTS, OFTEN USED FOR GOLD.
 Process:
2. PROCESSING OF MINERALS:
CRUSHING AND GRINDING: THE FIRST STEP IN
MINERAL PROCESSING, WHERE LARGE ROCKS ARE
CRUSHED INTO SMALLER PIECES.
CONCENTRATION: THE PROCESS OF SEPARATING
VALUABLE MINERALS FROM THE ORE, TYPICALLY
USING METHODS LIKE FLOTATION, MAGNETIC
SEPARATION, OR GRAVITY SEPARATION.
SMELTING AND REFINING: INVOLVES HEATING AND
CHEMICAL TREATMENT TO EXTRACT METALS FROM
ORES. FOR EXAMPLE, IRON IS SMELTED IN A BLAST
FURNACE, WHILE COPPER IS PURIFIED THROUGH
ELECTROLYSIS.
BENEFICIATION: ENHANCING THE QUALITY OF THE
ORE BY REMOVING IMPURITIES BEFORE FURTHER
PROCESSING.
 Process:
3. ENVIRONMENTAL IMPACT OF EXTRACTION:
LAND DEGRADATION: MINING OPERATIONS
CAN LEAD TO DEFORESTATION, SOIL
EROSION, AND THE DESTRUCTION OF
ECOSYSTEMS.
WATER POLLUTION: RUNOFF FROM MINING
SITES CAN CONTAMINATE RIVERS AND
GROUNDWATER WITH HEAVY METALS AND
CHEMICALS USED IN PROCESSING.
AIR POLLUTION: MINING AND PROCESSING
ACTIVITIES CAN RELEASE DUST AND TOXIC
EMISSIONS, CONTRIBUTING TO AIR
POLLUTION AND HEALTH HAZARDS.
Economic Importance of
Mineral Resources
 ECONOMIC IMPORTANCE OF
MINERAL RESOURCES

1. CONTRIBUTION TO GDP
2. JOB CREATION
3. INDUSTRIAL GROWTH
4.INTERNATIONAL TRADE
5. INFRASTRUCTURE DEVELOPMENT
Environmental Impact and
Sustainable Management
 ENVIRONMENTAL IMPACT AND
SUSTAINABLE MANAGEMENT

1.ENVIRONMENTAL CHALLENGES
HABITAT DESTRUCTION 3. RENEWABLE ALTERNATIVES
POLLUTION
WASTE MANAGEMENT

4. RECYCLING AND REUSE
2. SUSTAINABLE PRACTICES
REHABILITATION
REDUCING ENVIRONMENTAL
5. GLOBAL INITIATIVES
RESPONSIBLE MINING
Importance:
ECONOMIC GROWTH: ENERGY
RESOURCES ARE THE BACKBONE
OF INDUSTRIALIZATION AND
ECONOMIC DEVELOPMENT,
PROVIDING THE POWER
NECESSARY FOR
MANUFACTURING,
TRANSPORTATION, AND
INFRASTRUCTURE.
Importance:
MODERN LIVING: ACCESS
TO RELIABLE ENERGY
RESOURCES IS CRUCIAL FOR
MODERN CONVENIENCES,
FROM LIGHTING AND HEATING
TO COMMUNICATION AND
HEALTHCARE.
Energy Resources
ENERGY RESOURCES ARE
NATURAL MATERIALS FOUND IN
THE EARTH'S CRUST THAT CAN BE
EXTRACTED AND USED TO PRODUCE
ENERGY. THESE RESOURCES ARE
VITAL FOR POWERING HOMES,
INDUSTRIES, TRANSPORTATION,
AND MANY OTHER ASPECTS OF
MODERN LIFE.
 Types of
Energy Resources
Classification:
FOSSIL FUEL
NUCLEAR FUEL
RENEWABLE ENERGY

Fossil Fuel Nuclear Fuel Renewable Energy
Types of
Energy Resources:
FOSSIL FUELS: INCLUDE COAL, OIL, AND
NATURAL GAS, FORMED FROM THE
REMAINS OF ANCIENT PLANTS AND
ANIMALS OVER MILLIONS OF YEARS.
NUCLEAR FUELS: PRIMARILY URANIUM,
WHICH IS USED IN NUCLEAR REACTORS TO
GENERATE ELECTRICITY.
RENEWABLE RESOURCES: INCLUDE
GEOTHERMAL ENERGY, WIND, AND SOLAR
POWER, DERIVED FROM NATURAL
PROCESSES THAT ARE REPLENISHED OVER
TIME.
RENEWABLE NON-RENEWABLE
ENERGY ENERGY
Extraction and Use of
Energy Resources
 Process:
1. EXTRACTION METHODS:
MINING FOR FOSSIL FUELS: COAL IS
EXTRACTED THROUGH SURFACE OR
UNDERGROUND MINING. OIL AND
NATURAL GAS ARE EXTRACTED BY
DRILLING INTO THE EARTH’S CRUST,
OFTEN REQUIRING ADVANCED
TECHNOLOGY LIKE HYDRAULIC
FRACTURING (FRACKING).
URANIUM MINING: EXTRACTED
THROUGH TRADITIONAL MINING
METHODS OR IN-SITU LEACHING,
WHERE THE URANIUM IS DISSOLVED
AND PUMPED TO THE SURFACE.
 Process:
HARNESSING RENEWABLE ENERGY:
GEOTHERMAL ENERGY: WELLS ARE DRILLED
INTO GEOTHERMAL RESERVOIRS TO ACCESS
STEAM AND HOT WATER, WHICH CAN BE
USED TO DRIVE TURBINES FOR ELECTRICITY
GENERATION.
WIND ENERGY: WIND TURBINES ARE
INSTALLED IN AREAS WITH CONSISTENT
WIND PATTERNS, CONVERTING WIND INTO
MECHANICAL ENERGY, THEN INTO
ELECTRICITY.
SOLAR ENERGY: SOLAR PANELS ARE
INSTALLED TO CAPTURE SUNLIGHT, WHICH
IS THEN CONVERTED INTO ELECTRICITY
USING PHOTOVOLTAIC CELLS.
 Process:
2. ENERGY PRODUCTION:
ELECTRICITY GENERATION: FOSSIL FUELS,
URANIUM, AND RENEWABLE SOURCES ARE
USED IN POWER PLANTS TO GENERATE
ELECTRICITY. FOSSIL FUEL POWER PLANTS
BURN COAL, OIL, OR GAS TO PRODUCE STEAM
THAT DRIVES TURBINES. NUCLEAR PLANTS
USE URANIUM FISSION TO HEAT WATER AND
GENERATE STEAM. RENEWABLE ENERGY
PLANTS HARNESS NATURAL PROCESSES, SUCH
AS WIND TURNING TURBINES OR SUNLIGHT
GENERATING ELECTRICITY IN SOLAR PANELS.
TRANSPORTATION FUELS: OIL IS REFINED
INTO GASOLINE, DIESEL, AND JET FUEL,
WHICH POWER CARS, TRUCKS, AIRPLANES,
AND SHIPS.
 Process:
3. ENVIRONMENTAL IMPACT:
FOSSIL FUELS: BURNING FOSSIL FUELS RELEASES
CARBON DIOXIDE AND OTHER GREENHOUSE
GASES, CONTRIBUTING TO CLIMATE CHANGE. IT
ALSO PRODUCES POLLUTANTS THAT HARM AIR
QUALITY AND PUBLIC HEALTH.
NUCLEAR ENERGY: NUCLEAR POWER PRODUCES
NO GREENHOUSE GAS EMISSIONS DURING
OPERATION, BUT IT GENERATES RADIOACTIVE
WASTE, WHICH REQUIRES LONG-TERM
STORAGE AND MANAGEMENT.
RENEWABLE ENERGY: GENERALLY HAS A LOWER
ENVIRONMENTAL IMPACT, WITH MINIMAL
EMISSIONS DURING OPERATION. HOWEVER,
THE PRODUCTION AND INSTALLATION OF
RENEWABLE ENERGY INFRASTRUCTURE CAN
HAVE LOCALIZED ENVIRONMENTAL EFFECTS.
Water Resources
WATER RESOURCES REFER TO
THE SOURCES OF WATER THAT
ARE USEFUL OR POTENTIALLY
USEFUL FOR HUMANS,
INCLUDING RIVERS, LAKES,
GROUNDWATER, AND OCEANS.
THEY ARE CRUCIAL FOR
DRINKING, AGRICULTURE,
INDUSTRY, AND SUSTAINING
ECOSYSTEMS.
Types of Water Resources
 Classification:

SURFACE WATER
GROUND WATER
MARINE WATER

Surface Ground Marine
 Types of
Water Resources
SURFACE WATER: WATER FROM
RIVERS, LAKES, AND RESERVOIRS. IT IS
THE MOST ACCESSIBLE FORM OF
FRESHWATER.
GROUNDWATER: WATER STORED
BENEATH THE EARTH’S SURFACE IN
AQUIFERS, WHICH CAN BE TAPPED
THROUGH WELLS.
MARINE WATER: SALTWATER FROM
OCEANS AND SEAS, WHICH CAN BE
DESALINATED FOR USE IN AREAS
WHERE FRESHWATER IS SCARCE.
Water Sources
Importance:
ESSENTIAL FOR LIFE:
WATER IS VITAL FOR
ALL LIVING
ORGANISMS. IT IS
USED FOR DRINKING,
COOKING,
SANITATION, AND
HYGIENE.
Importance:
AGRICULTURE AND
INDUSTRY: WATER IS
CRITICAL FOR
IRRIGATION IN
AGRICULTURE, AS WELL
AS IN VARIOUS
INDUSTRIAL
PROCESSES.
Importance:
ECOSYSTEM SUPPORT:
WATER BODIES
SUPPORT AQUATIC
LIFE AND PROVIDE
HABITATS FOR
VARIOUS SPECIES,
MAINTAINING
BIODIVERSITY.
 Utilization and
Management of Water
Resources
 Process:
1. UTILIZATION IN DAILY LIFE:
DRINKING WATER: ENSURING ACCESS TO
CLEAN AND SAFE DRINKING WATER IS
ESSENTIAL FOR PUBLIC HEALTH. MUNICIPAL
WATER SYSTEMS TREAT AND DISTRIBUTE
WATER TO HOUSEHOLDS AND BUSINESSES.
AGRICULTURE: WATER IS USED EXTENSIVELY
IN AGRICULTURE FOR IRRIGATING CROPS.
EFFICIENT IRRIGATION PRACTICES LIKE
DRIP IRRIGATION HELP CONSERVE WATER
AND IMPROVE CROP YIELDS.
INDUSTRY: WATER IS USED IN
MANUFACTURING PROCESSES, POWER
GENERATION, AND AS A COOLING AGENT.
INDUSTRIES OFTEN REQUIRE LARGE
VOLUMES OF WATER, WHICH MUST BE
MANAGED SUSTAINABLY.
 Process:
2. WATER MANAGEMENT TECHNIQUES:
DAMS AND RESERVOIRS: CONSTRUCTED TO
STORE WATER, CONTROL FLOODING, AND
GENERATE HYDROELECTRIC POWER. WHILE
BENEFICIAL, THEY CAN DISRUPT
ECOSYSTEMS AND DISPLACE COMMUNITIES.
IRRIGATION SYSTEMS: TECHNOLOGIES LIKE
DRIP AND SPRINKLER IRRIGATION HELP
DISTRIBUTE WATER MORE EFFICIENTLY IN
AGRICULTURE, REDUCING WASTE AND
INCREASING PRODUCTIVITY.
WATER TREATMENT PLANTS: FACILITIES
THAT PURIFY WATER FROM RIVERS, LAKES,
OR GROUNDWATER BEFORE IT IS SUPPLIED
TO CONSUMERS. TREATMENT PROCESSES
REMOVE CONTAMINANTS AND PATHOGENS
TO ENSURE WATER SAFETY.
 Process:
3. ENVIRONMENTAL IMPACT:
WATER POLLUTION: CONTAMINATION FROM
INDUSTRIAL DISCHARGE, AGRICULTURAL
RUNOFF, AND SEWAGE CAN DEGRADE WATER
QUALITY, HARMING ECOSYSTEMS AND
HUMAN HEALTH.
OVER-EXTRACTION: EXCESSIVE
WITHDRAWAL OF WATER FROM RIVERS,
LAKES, AND AQUIFERS CAN LEAD TO
DEPLETION OF WATER RESOURCES, AFFECTING
THE AVAILABILITY OF WATER FOR FUTURE
GENERATIONS.
CLIMATE CHANGE: ALTERED WEATHER
PATTERNS DUE TO CLIMATE CHANGE CAN LEAD
TO DROUGHTS, FLOODS, AND CHANGES IN
WATER AVAILABILITY, CHALLENGING WATER
RESOURCE MANAGEMENT.
Soil Resources
SOIL RESOURCES ARE THE TOP
LAYER OF THE EARTH’S
SURFACE, CONSISTING OF A
MIXTURE OF ORGANIC MATTER,
MINERALS, GASES, LIQUIDS,
AND LIVING ORGANISMS. SOIL
SUPPORTS PLANT GROWTH,
INFLUENCES WATER CYCLES,
AND PLAYS A CRUCIAL ROLE IN
VARIOUS ECOLOGICAL
PROCESSES.
 Types of Soil:
TOPSOIL: THE UPPERMOST LAYER OF
SOIL, RICH IN ORGANIC MATERIAL
AND NUTRIENTS, ESSENTIAL FOR
PLANT GROWTH.
SUBSOIL: LOCATED BENEATH THE
TOPSOIL, IT CONTAINS MINERALS
AND LESS ORGANIC MATTER. IT
SUPPORTS PLANT ROOTS AND
RETAINS WATER AND NUTRIENTS.
BEDROCK: THE DEEPEST LAYER,
CONSISTING OF SOLID ROCK. OVER
TIME, WEATHERING PROCESSES
BREAK DOWN BEDROCK INTO SOIL.
Importance
AGRICULTURE: SOIL IS
FUNDAMENTAL FOR
GROWING CROPS AND
RAISING LIVESTOCK,
PROVIDING ESSENTIAL
NUTRIENTS AND A
MEDIUM FOR PLANT
ROOTS.
Importance
WATER FILTRATION:
SOILS FILTER AND
CLEAN WATER AS IT
PERCOLATES THROUGH,
HELPING TO MAINTAIN
GROUNDWATER
QUALITY.
Importance
ECOSYSTEM SUPPORT:
SOIL PROVIDES HABITAT
FOR COUNTLESS
ORGANISMS, INCLUDING
MICROORGANISMS,
INSECTS, AND PLANTS,
SUPPORTING
BIODIVERSITY.
Types of Soil
 1. SOIL HORIZONS
Types of Soil
O HORIZON (ORGANIC LAYER): COMPOSED MAINLY OF ORGANIC MATERIAL LIKE
DECOMPOSED LEAVES AND PLANTS. IT IS RICH IN NUTRIENTS AND SUPPORTS PLANT
GROWTH.
A HORIZON (TOPSOIL): THE TOPSOIL LAYER IS A MIX OF ORGANIC MATERIAL AND
MINERALS. IT IS CRUCIAL FOR AGRICULTURE AS IT CONTAINS THE MAJORITY OF A
SOIL’S NUTRIENTS.
B HORIZON (SUBSOIL): CONTAINS MINERALS LEACHED DOWN FROM THE TOPSOIL. IT
IS LESS FERTILE BUT IMPORTANT FOR WATER AND NUTRIENT STORAGE.
C HORIZON (PARENT MATERIAL): CONSISTS OF WEATHERED ROCK AND MINERAL
FRAGMENTS. IT IS THE SOURCE OF THE MINERALS IN THE SOIL.
R HORIZON (BEDROCK): THE DEEPEST LAYER, CONSISTING OF SOLID ROCK FROM
WHICH SOIL IS FORMED.
 2. SOIL TYPES
Types of Soil
SANDY SOIL: COARSE TEXTURE WITH LARGE PARTICLES, DRAINS
QUICKLY BUT HAS LOW NUTRIENT AND WATER-HOLDING
CAPACITY.
CLAY SOIL: FINE TEXTURE WITH SMALL PARTICLES, RETAINS
WATER WELL BUT DRAINS SLOWLY AND CAN BECOME COMPACTED.
SILT SOIL: MEDIUM-SIZED PARTICLES, RETAINS MOISTURE
BETTER THAN SANDY SOIL AND DRAINS BETTER THAN CLAY SOIL.
LOAM SOIL: A BALANCED MIXTURE OF SAND, SILT, AND CLAY,
IDEAL FOR AGRICULTURE DUE TO ITS FERTILITY AND GOOD
DRAINAGE.
 3. SOIL PROPERTIES
Types of Soil
TEXTURE: REFERS TO THE PROPORTION OF SAND, SILT, AND
CLAY IN SOIL. TEXTURE AFFECTS WATER RETENTION, DRAINAGE,
AND NUTRIENT AVAILABILITY.
STRUCTURE: THE ARRANGEMENT OF SOIL PARTICLES INTO
AGGREGATES OR CLUMPS. GOOD STRUCTURE IMPROVES
AERATION AND ROOT GROWTH.
PH: MEASURES SOIL ACIDITY OR ALKALINITY. MOST PLANTS
GROW BEST IN SLIGHTLY ACIDIC TO NEUTRAL SOILS (PH 6-7).
 Utilization and
Management of Soil
Resources
 Process
1. SOIL IN AGRICULTURE:
CROP PRODUCTION: SOIL
PROVIDES NUTRIENTS AND A
MEDIUM FOR ROOT GROWTH.
FERTILE SOIL IS ESSENTIAL FOR HIGH
CROP YIELDS.
SOIL MANAGEMENT PRACTICES:
TECHNIQUES LIKE CROP ROTATION,
COVER CROPPING, AND ORGANIC
AMENDMENTS ENHANCE SOIL
FERTILITY AND STRUCTURE.
 Process
2. SOIL CONSERVATION METHODS:
EROSION CONTROL: METHODS SUCH AS
CONTOUR PLOWING, TERRACING, AND
PLANTING COVER CROPS PREVENT SOIL
EROSION AND LOSS OF TOPSOIL.
WATER MANAGEMENT: TECHNIQUES
LIKE DRIP IRRIGATION AND RAINWATER
HARVESTING REDUCE WATER RUNOFF AND
SOIL DEGRADATION.
ORGANIC FARMING: UTILIZES NATURAL
FERTILIZERS AND PRACTICES THAT
MAINTAIN SOIL HEALTH AND REDUCE
DEPENDENCY ON CHEMICAL INPUTS.
 Process
3. SOIL POLLUTION AND
DEGRADATION:
CONTAMINATION: POLLUTION
FROM INDUSTRIAL ACTIVITIES,
PESTICIDES, AND HEAVY METALS
CAN DEGRADE SOIL QUALITY AND
AFFECT PLANT GROWTH.
DEPLETION: OVER-FARMING AND
DEFORESTATION CAN LEAD TO SOIL
DEPLETION AND REDUCED FERTILITY,
NECESSITATING SOIL RESTORATION
EFFORTS.
Economic Importance
of Soil Resources
 1. AGRICULTURAL PRODUCTIVITY
Economic Importance

SOIL IS A KEY RESOURCE FOR GROWING
CROPS AND RAISING LIVESTOCK,
IMPACTING FOOD SECURITY AND
AGRICULTURAL ECONOMIES. FERTILE SOIL
SUPPORTS HIGH YIELDS AND SUSTAINABLE
FARMING PRACTICES.
 2. CONSTRUCTION DEVELOPMENT
Economic Importance

SOIL PROPERTIES INFLUENCE THE
SUITABILITY OF LAND FOR CONSTRUCTION
AND INFRASTRUCTURE PROJECTS. SOIL
STABILITY AND COMPOSITION ARE
CRITICAL FOR BUILDING FOUNDATIONS
AND LANDSCAPING.
 3. ENVIRONMENTAL BENEFITS
Economic Importance

HEALTHY SOILS CONTRIBUTE TO ECOSYSTEM
SERVICES SUCH AS CARBON
SEQUESTRATION, WATER FILTRATION, AND
HABITAT PROVISION. THESE BENEFITS HAVE
INDIRECT ECONOMIC VALUE BY SUPPORTING
NATURAL PROCESSES AND REDUCING THE
NEED FOR ARTIFICIAL INTERVENTIONS.
 4. JOB CREATION
Economic Importance

SOIL MANAGEMENT AND CONSERVATION
CREATE JOBS IN AGRICULTURE,
ENVIRONMENTAL SCIENCE, AND LAND
MANAGEMENT. ROLES INCLUDE SOIL
SCIENTISTS, AGRONOMISTS, AND
CONSERVATIONISTS.
 5. GLOBAL TRADE
Economic Importance

SOIL FERTILITY AFFECTS THE PRODUCTION
OF AGRICULTURAL EXPORTS, INFLUENCING
GLOBAL TRADE DYNAMICS. COUNTRIES
WITH RICH SOILS CAN PRODUCE AND
EXPORT SURPLUS CROPS, IMPACTING THE
GLOBAL FOOD MARKET.
 Environmental Impact
and
Sustainable Management
 1. ENVIRONMENTAL CHALLENGES
Sustainable Management
Environmental Impact &

SOIL EROSION: CAUSED BY WIND AND WATER, EROSION LEADS
TO THE LOSS OF TOPSOIL, WHICH AFFECTS AGRICULTURAL
PRODUCTIVITY AND ECOSYSTEM HEALTH.
SOIL CONTAMINATION: POLLUTION FROM INDUSTRIAL
ACTIVITIES, HEAVY METALS, AND CHEMICALS CAN DEGRADE
SOIL QUALITY AND HARM PLANT AND ANIMAL LIFE.
DESERTIFICATION: OVERGRAZING, DEFORESTATION, AND
POOR LAND MANAGEMENT CAN LEAD TO DESERTIFICATION,
WHERE FERTILE LAND BECOMES BARREN AND UNPRODUCTIVE.
 2. SUSTAINABLE SOIL MANAGEMENT
Sustainable Management
Environmental Impact &

CONSERVATION PRACTICES: IMPLEMENTING PRACTICES SUCH
AS NO-TILL FARMING, MAINTAINING GROUND COVER, AND
BUILDING TERRACES TO PROTECT AND PRESERVE SOIL.
RESTORATION PROJECTS: REHABILITATING DEGRADED SOILS
THROUGH REFORESTATION, ORGANIC AMENDMENTS, AND
SUSTAINABLE LAND MANAGEMENT PRACTICES.
EDUCATION AND RESEARCH: PROMOTING AWARENESS AND
RESEARCH ON SOIL HEALTH AND CONSERVATION TO IMPROVE
SOIL MANAGEMENT PRACTICES AND TECHNOLOGIES.
 3. TECHNOLOGY & INNOVATION
Sustainable Management
Environmental Impact &

SOIL TESTING: ADVANCES IN SOIL TESTING AND ANALYSIS HELP
FARMERS AND LAND MANAGERS UNDERSTAND SOIL CONDITIONS
AND OPTIMIZE FERTILIZATION AND CROP MANAGEMENT.
PRECISION AGRICULTURE: UTILIZES TECHNOLOGY LIKE GPS AND
REMOTE SENSING TO APPLY SOIL MANAGEMENT PRACTICES MORE
ACCURATELY AND EFFICIENTLY.
SOIL HEALTH MONITORING: TECHNOLOGIES FOR MONITORING SOIL
HEALTH AND QUALITY HELP TRACK CHANGES OVER TIME AND
INFORM SUSTAINABLE LAND MANAGEMENT STRATEGIES.
 4. GLOBAL COOPERATION
Sustainable Management
Environmental Impact &

INTERNATIONAL AGREEMENTS: INITIATIVES LIKE THE UNITED
NATIONS' SUSTAINABLE DEVELOPMENT GOALS (SDGS)
INCLUDE TARGETS FOR IMPROVING SOIL HEALTH AND
MANAGING LAND RESOURCES SUSTAINABLY.
KNOWLEDGE SHARING: GLOBAL NETWORKS AND
ORGANIZATIONS SHARE KNOWLEDGE AND BEST PRACTICES
FOR SOIL CONSERVATION AND SUSTAINABLE MANAGEMENT
ACROSS DIFFERENT REGIONS.
Human Activity and the Environment
HUMAN ACTIVITY REFERS TO THE VARIOUS
ACTIONS AND PROCESSES UNDERTAKEN BY
PEOPLE THAT IMPACT THE NATURAL WORLD.
THIS INCLUDES ACTIVITIES RELATED TO
AGRICULTURE, INDUSTRY,
TRANSPORTATION, AND URBAN
DEVELOPMENT. THE ENVIRONMENT
ENCOMPASSES ALL NATURAL
SURROUNDINGS, INCLUDING AIR, WATER,
LAND, AND ECOSYSTEMS.
 Types of Human Activities
AGRICULTURAL PRACTICES: FARMING AND
LIVESTOCK RAISING THAT AFFECT LAND USE, WATER
RESOURCES, AND BIODIVERSITY.
INDUSTRIAL PROCESSES: MANUFACTURING AND
ENERGY PRODUCTION THAT IMPACT AIR AND WATER
QUALITY, AS WELL AS LAND USE.
TRANSPORTATION: MOVEMENT OF PEOPLE AND
GOODS THAT INFLUENCES AIR QUALITY, ENERGY
CONSUMPTION, AND LAND USE.
URBAN DEVELOPMENT: CONSTRUCTION AND
EXPANSION OF CITIES AND INFRASTRUCTURE THAT
AFFECT LAND USE, ECOSYSTEMS, AND RESOURCE
CONSUMPTION.
 Importance:
ENVIRONMENTAL HEALTH:
UNDERSTANDING THE
IMPACTS OF HUMAN
ACTIVITIES HELPS ADDRESS
ISSUES LIKE POLLUTION,
RESOURCE DEPLETION, AND
CLIMATE CHANGE.
 Importance:
SUSTAINABLE DEVELOPMENT:
BALANCING HUMAN NEEDS
WITH ENVIRONMENTAL
PROTECTION IS CRUCIAL FOR
LONG-TERM SUSTAINABILITY
AND QUALITY OF LIFE.
 Importance:
ECOSYSTEM PROTECTION:
HUMAN ACTIVITIES CAN
DISRUPT ECOSYSTEMS AND
BIODIVERSITY, AFFECTING THE
BALANCE OF NATURAL
SYSTEMS.
 Impacts of Human
Intervene/Activities
 Classification:
TRANSPORTATION
URBAN DEVELOPMENT

Transportation Urban Development
 Classification:
AGRICULTURAL PRACTICES
INDUSTRIAL PROCESSES

Agricultural Practices Industrial Processes
Environmental Challenges
 Process
1. CLIMATE CHANGE:
GREENHOUSE GAS EMISSIONS: HUMAN ACTIVITIES,
ESPECIALLY THE BURNING OF FOSSIL FUELS,
INCREASE GREENHOUSE GAS CONCENTRATIONS IN
THE ATMOSPHERE, LEADING TO GLOBAL WARMING
AND CLIMATE CHANGES.

EXTREME WEATHER EVENTS: CHANGES IN CLIMATE
PATTERNS CONTRIBUTE TO MORE FREQUENT AND
SEVERE WEATHER EVENTS SUCH AS HURRICANES,
HEATWAVES, AND FLOODS.
 Process
2. RESOURCE DEPLETION:
NON-RENEWABLE RESOURCES:
OVEREXPLOITATION OF RESOURCES LIKE
FOSSIL FUELS, MINERALS, AND WATER CAN
LEAD TO SHORTAGES AND ECOLOGICAL
IMBALANCES.
DEFORESTATION: CLEARING FORESTS FOR
AGRICULTURE OR DEVELOPMENT REDUCES
BIODIVERSITY, DISRUPTS WATER CYCLES,
AND CONTRIBUTES TO CARBON EMISSIONS.
 Process
3. POLLUTION:
AIR POLLUTION: EMISSIONS FROM
INDUSTRIAL ACTIVITIES, VEHICLES, AND
BURNING OF FOSSIL FUELS DEGRADE
AIR QUALITY AND IMPACT HEALTH.
WATER POLLUTION: CONTAMINANTS
FROM AGRICULTURE, INDUSTRY, AND
URBAN AREAS CAN HARM AQUATIC
ECOSYSTEMS AND MAKE WATER
UNSAFE FOR CONSUMPTION.
 Process
4. BIODIVERSITY LOSS:
HABITAT DESTRUCTION: HUMAN ACTIVITIES
LIKE DEFORESTATION AND URBANIZATION
DESTROY NATURAL HABITATS, LEADING TO
SPECIES EXTINCTION AND REDUCED
BIODIVERSITY.
OVEREXPLOITATION: HUNTING, FISHING,
AND TRADING OF WILDLIFE CAN
DEPLETE SPECIES POPULATIONS AND
DISRUPT ECOSYSTEMS.
Sustainable Practices and Solutions
 Process
1. SUSTAINABLE AGRICULTURE:
ORGANIC FARMING: USES NATURAL
FERTILIZERS AND PEST CONTROL METHODS TO
REDUCE ENVIRONMENTAL IMPACT AND
MAINTAIN SOIL HEALTH.
CONSERVATION TILLAGE: REDUCES SOIL
EROSION AND MAINTAINS SOIL STRUCTURE BY
MINIMIZING TILLAGE AND LEAVING CROP
RESIDUES ON THE SOIL SURFACE.
WATER-EFFICIENT IRRIGATION: TECHNIQUES
SUCH AS DRIP IRRIGATION AND RAINWATER
HARVESTING IMPROVE WATER USE EFFICIENCY
IN AGRICULTURE.
 Process
2. INDUSTRIAL INNOVATIONS:
CLEANER TECHNOLOGIES: ADOPTING TECHNOLOGIES
THAT REDUCE EMISSIONS AND WASTE, SUCH AS
CLEANER PRODUCTION METHODS AND ENERGY-
EFFICIENT MACHINERY.
RECYCLING AND WASTE MANAGEMENT: IMPLEMENTING
RECYCLING PROGRAMS AND WASTE REDUCTION
STRATEGIES TO MINIMIZE LANDFILL USE AND
ENVIRONMENTAL IMPACT.
GREEN ENERGY: TRANSITIONING TO RENEWABLE
ENERGY SOURCES, SUCH AS SOLAR AND WIND, TO
REDUCE RELIANCE ON FOSSIL FUELS AND LOWER
GREENHOUSE GAS EMISSIONS.
 Process
3. SUSTAINABLE TRANSPORTATION:
PUBLIC TRANSIT: INVESTING IN PUBLIC
TRANSPORTATION SYSTEMS REDUCES THE NUMBER
OF PRIVATE VEHICLES ON THE ROAD AND LOWERS
EMISSIONS.
ELECTRIC VEHICLES: PROMOTING THE USE OF
ELECTRIC AND HYBRID VEHICLES TO DECREASE
RELIANCE ON FOSSIL FUELS AND REDUCE AIR
POLLUTION.
BIKE AND PEDESTRIAN INFRASTRUCTURE:
DEVELOPING INFRASTRUCTURE FOR CYCLING AND
WALKING ENCOURAGES ALTERNATIVE, ECO-FRIENDLY
TRANSPORTATION OPTIONS.
 Process
4. URBAN PLANNING:
GREEN BUILDING PRACTICES: DESIGNING BUILDINGS
WITH ENERGY-EFFICIENT FEATURES AND USING
SUSTAINABLE MATERIALS TO REDUCE
ENVIRONMENTAL IMPACT.
GREEN SPACES: INCORPORATING PARKS, GREEN
ROOFS, AND URBAN FORESTS INTO CITY PLANNING
TO ENHANCE BIODIVERSITY AND IMPROVE QUALITY
OF LIFE.
WASTE REDUCTION: IMPLEMENTING WASTE
SEPARATION AND RECYCLING PROGRAMS IN URBAN
AREAS TO MANAGE WASTE EFFECTIVELY AND
REDUCE ENVIRONMENTAL POLLUTION.
Global Cooperation and Policy
 Process
1. INTERNATIONAL AGREEMENTS:
CLIMATE AGREEMENTS: GLOBAL INITIATIVES
LIKE THE PARIS AGREEMENT AIM TO LIMIT
GREENHOUSE GAS EMISSIONS AND COMBAT
CLIMATE CHANGE THROUGH INTERNATIONAL
COOPERATION.
CONSERVATION TREATIES: AGREEMENTS
SUCH AS THE CONVENTION ON BIOLOGICAL
DIVERSITY WORK TO PROTECT
ENDANGERED SPECIES AND PRESERVE
ECOSYSTEMS.
 Process
2. NATIONAL POLICIES:
ENVIRONMENTAL REGULATIONS:
GOVERNMENTS IMPLEMENT LAWS AND
REGULATIONS TO CONTROL POLLUTION,
MANAGE NATURAL RESOURCES, AND
PROTECT ECOSYSTEMS.
SUSTAINABLE DEVELOPMENT GOALS (SDGS):
THE UNITED NATIONS’ SDGS INCLUDE
TARGETS FOR ENVIRONMENTAL
SUSTAINABILITY, CLIMATE ACTION, AND
RESPONSIBLE CONSUMPTION.
 Process
3. COMMUNITY ENGAGEMENT:
PUBLIC AWARENESS: EDUCATING
COMMUNITIES ABOUT ENVIRONMENTAL
ISSUES AND ENCOURAGING SUSTAINABLE
PRACTICES AT THE INDIVIDUAL AND LOCAL
LEVELS.
CITIZEN PARTICIPATION: INVOLVING
COMMUNITIES IN ENVIRONMENTAL DECISION-
MAKING AND CONSERVATION EFFORTS TO
PROMOTE STEWARDSHIP AND
ACCOUNTABILITY.
 Process
4. TECHNOLOGICAL ADVANCEMENTS:
ENVIRONMENTAL MONITORING:
USING TECHNOLOGY TO TRACK
ENVIRONMENTAL CHANGES, MEASURE
POLLUTION LEVELS, AND ASSESS THE
EFFECTIVENESS OF CONSERVATION
EFFORTS.
INNOVATION IN SUSTAINABILITY:
DEVELOPING NEW TECHNOLOGIES AND
SOLUTIONS TO ADDRESS ENVIRONMENTAL
CHALLENGES AND PROMOTE SUSTAINABLE
DEVELOPMENT.