ENG 2013 Environmental Science and Engineering M1 - Nature and Ecology (Part 1) PDF

Summary

This document provides an overview of environmental science and engineering topics, focusing on the concept of ecology and its different branches. The text explains the core principles and applications within different areas of environmental science. No specific instructor or institutions are indicated.

Full Transcript

ENG 2013
Environmental Science and Engineering

M1 – Nature and Ecology (Part 1)
Definitions of Ecology

❑From the Greek root οικος (oikos), “at home”, and ολιγο (oligo), “the
study of”
❑“By ecology we mean the body of knowledge concerning the
economy of Nature – the investigation of the total relations of the
animal to its inorganic and organic environment.” (Haeckle, 1870)
❑In the 1890s, Burdon-Sanderson elevated Ecology to one of the three
natural divisions of Biology: Physiology, Morphology, Ecology
❑“Scientific natural history” (Elton, 1927)
❑“The scientific study of the distribution and abundance of
organisms” (Andrewartha, 1961)
❑“The structure and function of Nature” (Odum, 1963)

M1 - Nature and Ecogloy (Part 1)
Our Definition of Ecology

❑“Ecology is the scientific study of the
processes regulating the distribution and
abundance of organisms and the interactions
among them, and the study of how these
organisms in turn mediate the transport and
transformation of energy and matter in the
biosphere (i.e. the study of the design of
ecosystem structure and function).”

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑ Applied Ecology
❑Using ecological principles to
maintain conditions necessary for
the continuation of present-day
life on earth.

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑Industrial Ecology
❑The design of the industrial infrastructure such that it consists of a
series of interlocking "technological ecosystems" interfacing with global
natural ecosystems.
❑Industrial ecology takes the pattern and processes of natural
ecosystems as a design for sustainability. It represents a shift in
paradigm from conquering nature to becoming nature.

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑Ecological Engineering
❑Unlike industrial ecology, the
focus of Ecological Engineering is
on the manipulation of natural
ecosystems by humans for our
purposes, using small amounts of
supplemental energy to control
systems in which the main energy
drives are still coming from non-
human sources.
❑It is the design of new ecosystems
for human purposes, using the
self-organizing principles of
natural ecosystems.

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑Ecological Engineering
❑A popular definition of ecological
engineering is:
“the design of human society
with its natural environment for
the benefit of both.”
What is the logical flaw in this
definition?

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑Ecological Economics
❑Integrating ecology and economics in such a way that economic and
environmental policies are reinforcing rather than mutually destructive.

ECONOMICS

Supply Demand

CONTROL
Environmental
Nature Policies
Man

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑Urban ecology
❑For ecologists, urban ecology
is the study of ecology in
urban areas, specifically the
relationships, interactions,
types and numbers of species
found in urban habitats.
❑Also, the design of
sustainable cities, urban
design programs that
incorporate political,
infrastructure and economic
considerations.

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑Conservation Biology
❑The application of diverse
fields and disciplines to
the conservation of
biological diversity.
❑Restoration Biology
❑Application of ecosystem
ecology to the restoration
of deteriorated landscapes
in an attempt to bring it
back to its original state as
much as possible.
Example: prarie grass.

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑Landscape Ecology
❑Landscape ecology is
concerned with spatial
patterns in the landscape and
how they develop, with an
emphasis on the role of
disturbance, including human
The Paraguay-Parana River before and after the
construction of the Yacyreta Dam in 1985 impacts” (Smith and Smith)
❑It is a relatively new branch of
ecology, that employs Global
Information Systems. The goal
is to predict the responses of
different organisms to changes
in landscape, to ultimately
facilitate ecosystem
Migration pattern of the Monarch butterfly flying south
management.
to Mexico in autumn to breed in warmer climate.

M1 - Nature and Ecogloy (Part 1)
Beyond Fundamental Ecology

❑All these disciplines require an understanding of the "organizing
principles" of ecosystems, i.e., their ecology.
❑This involves the detailed study of the structure and function of
ecosystems in their undisturbed state, and using their designs to:
❑determine the resilience of ecosystem functions to human activities
❑ design ecosystems which function in the service of human beings with
minimal fossil energy input (ideally none) and minimal waste
❑design the industrial infrastructure
❑integrate the value of "goods and services" of natural ecosystems into the
global economic system.

M1 - Nature and Ecogloy (Part 1)
 ENG 2013
Environmental Science and Engineering

M1 – Nature and Ecology (Part 2)
What is “Sustainability”?

Sustainability is a property of a human
society in which ecosystems (including
humans) are managed such that the
conditions supporting present day life
on Earth can continue.

M1 - Nature and Ecology (Part 2)
Levels of Studying Ecology

❑Biosphere
❑The Earth’s ecosystem interacting with the physical environment as a whole to maintain a
steady state system intermediate in the flow of energy between the high energy input of the
Sun and the thermal sink of space (merges with atmosphere, lithosphere, hydrosphere…).
❑Biome
❑Large scale areas of similar vegetation and climatic characteristics.
❑Ecosystem
❑Set of organisms and abiotic components connected by the exchange of matter and energy
(forest, lake, coastal ocean). Or, “the smallest units that can sustain life in isolation from all
but atmospheric surroundings.”
❑Community
❑Interacting populations which significantly affect each other’s distributions and abundance
(intertidal, hot spring, wetland).
❑Population
❑Group of interacting and interbreeding organisms
❑Cell/Organism
❑Organelle → Molecule → Atom

M1 - Nature and Ecology (Part 2)
M1 - Nature and Ecology (Part 2)
M1 - Nature and Ecology (Part 2)
Biosphere

❑The biosphere is made up
of parts of the Earth where
life exists.
❑Scientists describe the
Earth in terms of “spheres”
❑Lithosphere: The solid
surface of the Earth
❑Atmosphere: The layer of air
that stretches above the
lithosphere
❑Hydrosphere: Earth’s water –
on the surface, in the
ground, and in the air
❑The biosphere overlaps all
these spheres.

M1 - Nature and Ecology (Part 2)
Origin of the Biosphere

❑The biosphere has existed for about 3.5 billion years
❑Prokaryotes
❑The biosphere’s earliest lifeforms
❑Single-celled organisms (e.g. bacteria, archaea)
❑Survived without oxygen
❑Some prokaryotes developed a unique chemical process called
photosynthesis.
❑Photosynthesis: Using sunlight to make simple sugars and oxygen out of
water and carbon dioxide.
❑The photosynthetic organisms multiplied and thrived. Over a long
period of time, they changed the biosphere – changing the
atmosphere into a mix of oxygen and other gases that could sustain
new forms of life.

M1 - Nature and Ecology (Part 2)
Origin of the Biosphere

❑More complex lifeforms evolved
❑Plants and other photosynthetic species
developed
❑Animals which consume plants (and other
animals) evolved
❑Bacteria and other organisms evolved to
decompose (break down) dead plants and
animals
❑The biosphere benefits from this food web.
❑The remains of dead plants and animals release
nutrients into the soil and ocean. These
nutrients are reabsorbed by growing plants.
❑This exchange of food and energy makes the
biosphere a self-supporting and self-regulating
system.

M1 - Nature and Ecology (Part 2)
Origin of the Biosphere

❑The biosphere is sometimes thought of as one large ecosystem.
More often, it the biosphere is described as having many ecosystems.

M1 - Nature and Ecology (Part 2)
Man and the Biosphere

❑People play an important
part in maintaining the flow
of energy in the biosphere.
Sometimes, however,
people disrupt the flow.
❑Oxygen level decrease and
carbon dioxide increase in
the atmosphere when people
clear forests and burn fossil
fuels such as coal and oil.
❑Oil spills and industrial
wastes threaten life in the
hydrosphere.

M1 - Nature and Ecology (Part 2)
Man and the Biosphere

❑In the early 1970s, the United
Nations established a project
called Man and the Biosphere
Programme (MAB), which
promotes sustainable
development.
❑A network of biosphere
reserves exists to establish a
working, balanced relationship
between people and the natural
world.
❑Currently, there are
563 biosphere reserves all over
the world.

M1 - Nature and Ecology (Part 2)
Man and the Biosphere

❑The first biosphere reserve
was established in Yangambi,
Democratic Republic of Congo.
❑Yangambi, in the fertile Congo
River Basin, has 32,000 species
of trees and such endemic
species as forest elephants and
red river hogs.
❑The biosphere reserve at
Yangambi supports activities
such as sustainable agriculture,
hunting, and mining.

M1 - Nature and Ecology (Part 2)
 ENG 2013
Environmental Science and Engineering

M1 – Nature and Ecology (Part 3)
Environmental Science

❑Environmental science is an interdisciplinary academic field that
draws on ecology, geology, meteorology, biology, chemistry,
engineering, and physics to study environmental problems and
human impacts on the environment.
❑Environmental science in its broadest sense encompasses all the
fields of natural science.
❑Natural science is the study of nature and the physical world.

M1 - Nature and Ecolgoy (Part 3)
Environmental Engineering

❑Environmental engineering is a profession that applies mathematics
and science to utilize the properties of matter and sources of energy
in the solution of problems of environmental sanitation.
❑Environmental engineers need to be aware of the lessons of the
past—how problems came about and how scientists, engineers,
policy makers, and others worked together to solve them.
❑We then need to apply those lessons as appropriate to solve current
problems and prevent similar mistakes in the future.

M1 - Nature and Ecolgoy (Part 3)
Historical Perspective

❑In the beginning of a civilization, providing clean water and
managing wastes became necessary.
❑For ancient cities, the availability of a dependable water source
often meant the difference between survival and destruction.
❑Wells and aqueducts
❑Facilities for civilians (mid-1700s)
❑Public health and sanitation (water and waste management)
❑Diseases from contaminated air and water
❑Acute concerns: Pollutions (air, water, land, noise, etc.)

M1 - Nature and Ecolgoy (Part 3)
Historical Perspective

❑Complex and chronic problems
❑Climate change
❑Depleting aquifers (groundwaters)
❑Indoor air pollution
❑Global transport and usage of toxic chemicals
❑Combined impacts of complex mixtures of human-made chemicals in
wastewater effluents, rivers and streams
❑Lack of information on the effect on human and environmental health and
safety of rapidly emerging new materials

M1 - Nature and Ecolgoy (Part 3)
Historical Perspective

❑In the 21st century it is apparent that ecosystems and the natural
sources on Earth are not abundant.
❑Preserving and maintaining the health, economic, and social well-
being of people depends on preserving and maintaining the integrity
of ecosystems and the ecosystem services they provide.
❑The solution is the well-being of both economy and the
environment.

M1 - Nature and Ecolgoy (Part 3)
Ecosystems

❑Ecosystems are communities of organisms that interact with one
another and with their physical and chemical environment, including
sunlight, rainfall, and soil nutrients.
❑Within each ecosystem are habitats, which are defined as the place
where a population of organisms live.
❑Although ecosystems change naturally, human activity can speed up
natural processes by several orders of magnitude (in terms of time).
❑Examples:
❑Large-scale agricultural operations, although producing inexpensive food to
feed millions, can result in the release of pesticides, fertilizers, and carbon
dioxide and other greenhouse gases to the environment.
❑Hydroelectric power is seen as a clean, renewable energy source. However,
dam construction can have detrimental effects on river ecosystems,
drastically reducing fish populations as well as causing erosion of soil and
vegetation during powerful water surges.

M1 - Nature and Ecolgoy (Part 3)
Introduction to the Principles of
Environmental Science and Engineering
❑As the problems faced by environmental engineers continue to grow
more complex, there is a growing need for principles and
frameworks to guide the development of solutions.
❑In 2003, approximately 65 engineers and scientists convened in
Sandestin, Florida to develop a set of principles for (green)
sustainable engineering.
❑Sustainable engineering transforms existing engineering disciplines
and practices into those that promote sustainability.

M1 - Nature and Ecolgoy (Part 3)
Sandestin Principles for Sustainable Engineering

1. Engineer processes and products holistically, use systems analysis,
and integrate environmental impact assessment tools.
2. Conserve and improve natural ecosystems while protecting human
health and well-being.
3. Use life-cycle thinking in all engineering activities.
4. Ensure that all material and energy inputs and outputs are as
inherently safe and benign as possible.
5. Minimize depletion of natural resources.
6. Strive to prevent waste.
7. Develop and apply engineering solutions, while being cognizant of
local geography, aspirations, and cultures.
8. Create engineering solutions beyond current or dominant
technologies; improve, innovate, and invent (technologies) to
achieve sustainability.
9. Actively engage communities and stakeholders in development of
engineering solutions.

M1 - Nature and Ecolgoy (Part 3)
Sustainability

❑A common goal has emerged throughout the world: sustainable
development (also referred as sustainability)
❑Defined by a United Nations commission in the Brundtland Report as
“development that meets the needs of the present without
compromising the ability of future generations to meet their own
needs.”

M1 - Nature and Ecolgoy (Part 3)
WCED and UNCED

❑In 1983, the United Nations created the World Commission on
Environment and Development (later known as the Brundtland
Commission), which defined sustainable development.
❑In 1992, the first United Nations Conference on Environment and
Development (UNCED) or Earth Summit was held in Rio de Janeiro,
Brazil, where the first agenda for Environment and Development, also
known as Agenda 21, was developed wherein 178 governments
voted to adopt the program.

M1 - Nature and Ecolgoy (Part 3)
Agenda 21

❑A 351-page document divided into 40
chapters grouped into 4 sections:
1. Social and Economic Dimensions
2. Conservation and Management of
Resources for Development
3. Strengthening the Role of Major Groups
4. Means of Implementation

M1 - Nature and Ecolgoy (Part 3)
Agenda 21

❑Section I: Social and Economic Dimensions is directed toward combating
poverty, especially in developing countries, changing consumption patterns,
promoting health, achieving a more sustainable population, and sustainable
settlement in decision making.
❑Section II: Conservation and Management of Resources for Development
includes atmospheric protection, combating deforestation, protecting fragile
environments, conservation of biological diversity (biodiversity), control of
pollution and the management of biotechnology, and radioactive wastes.
❑Section III: Strengthening the Role of Major Groups includes the roles of
children and youth, women, NGOs, local authorities, business and industry,
and workers; and strengthening the role of indigenous peoples, their
communities, and farmers.
❑Section IV: Means of Implementation includes science, technology transfer,
education, international institutions, and financial mechanisms.

M1 - Nature and Ecolgoy (Part 3)
Agenda 21

❑The "21" in Agenda 21 refers to the original target of the 21st
century to achieve their development goals by then.
❑It has been stated and modified at subsequent UN conferences
(1997, 2002, 2012, 2015).

M1 - Nature and Ecolgoy (Part 3)
Agenda Timeline

❑Rio +5 (1997)
❑In Rio, it was agreed that a five-year review of
Earth Summit progress would be made by the
United Nations General Assembly.
❑They took stock of how well countries,
international organizations and sectors of civil
society have responded to the challenge of the
Earth Summit.
❑Millennium Summit (2000)
❑Established the Millennium Development
Goals (MDGs) which were eight international
development goals for the year 2015.

M1 - Nature and Ecolgoy (Part 3)
Agenda Timeline

❑Rio +10 (2002)
❑Organized 10 years after Rio to develop consensus on the sustainable
development by the United Nations.
❑The alarming deterioration in the earth's ecosystems compelled the global
leaders to organize the summit to pursue new initiatives on the
implementation of sustainable development and the building of a
prosperous and secure future for their citizens.
❑Rio +20 (2012)
❑Resulted in a focused political outcome document which contains clear and
practical measures for implementing sustainable development.

M1 - Nature and Ecolgoy (Part 3)
Agenda 2030

❑It was realized that 2000 was an overly optimistic date, its new
timeline targets year 2030.
❑Agenda 2030, also known as the Sustainable Development Goals
(SDGs), was a set of goals decided upon at the UN Sustainable
Development Summit (January 2015).
❑On September 25, 2015, 193 countries of the UN General Assembly
adopted Agenda 2030.

M1 - Nature and Ecolgoy (Part 3)
M1 - Nature and Ecolgoy (Part 3)
 ENG 2013
Environmental Science and Engineering

M2 – Natural Systems and Resources (Part 1)
Ecosystem

❑An ecosystem is a community of interacting organisms and the
physical environment in which they live.
❑Living thing such as animals, insects, plants, humans
❑Inorganic matter such as rocks and metals
❑Natural forces such as the flow of water, photosynthesis
❑All these link together and interact to form a complex web of life.
❑It is easy to forget that humans are part of this natural system
❑People have the ability to change (and to a limited extent) control their
physical environment to suit their needs
❑Man-made systems and technologies utilize natural resources to uphold our
way of life
❑Our actions impact how these natural systems work

M2 - Natural Systems and Resources (Part 1)
Natural Systems

❑Water system
❑Includes streams, lakes, wetlands, groundwater, stormwater runoff, and
shorelines
❑Land system
❑Involves soils, rocks, plants, as well as the underlying geology and
topography
❑Air system
❑Involves air quality, climate and energy (e.g. global warming, wind, and
storms)

❑All three systems are interdependent. An impact to an element
within one system affects the resources in the other two systems.

M2 - Natural Systems and Resources (Part 1)
Natural Resource

❑A natural resource is any material or substance that exist in nature
and is valued by people to serve and enhance the community.
❑Natural resources directly contribute to the development of the
physical health and well-being of species; and are essential for its
continual survival.
❑On the basis of origin, natural resources can be divided into two
types:
❑Biotic: Obtained from the biosphere (living and organic material), and the
materials that can be obtained from them.
❑Abiotic: Resources that come from non-living, non-organic material.
❑On the basis of recovery rate, resources can be categorized as:
❑Renewable: Resources that can be replenished naturally.
❑Non-renewable: Resources that form slowly, or those that do not form in the
environment.

M2 - Natural Systems and Resources (Part 1)
 ENG 2013
Environmental Science and Engineering

M2 – Natural Systems and Resources (Part 2)
Water Resources

❑Water resources are natural sources
of water that are potentially useful.
❑All living things require water to
grow and reproduce.
❑Water is used in agricultural,
industrial, household, recreational,
and environmental activities.
❑Of all the water on Earth, 97% is salt
water and only 3% is fresh water.
❑About two-thirds of the fresh water is
frozen in glaciers and polar ice caps.
❑The remainder is found mainly as
groundwater, with only a small fraction
present above ground or in the air.

M2 - Natural Systems and Resources (Part 2)
Sources of Fresh Water

❑Surface water
❑Water that is in a river, lake, or fresh
water wetland.
❑Surface water is naturally replenished
by precipitation, and lost through
discharge to the oceans, evaporation,
and groundwater recharge (see water
cycle).
❑Groundwater
❑Water that is located in the subsurface
pore space of soil and rocks.
❑It is also water flowing in aquifers
below the water table
❑Groundwater input comes from
seepage from surface water.

M2 - Natural Systems and Resources (Part 2)
Sources of Fresh Water

❑Frozen water
❑It has been proposed to make use of
icebergs as a water source.
❑The ice and snow in the Himalayas
supply fresh water to ten of Asia’s
largest rivers.
❑Desalination
❑Desalination is an artificial process by
which sea water is converted into
fresh water.
❑The most common processes in use
are distillation and reverse osmosis.
❑Not usually economically viable as a
fresh water source.

M2 - Natural Systems and Resources (Part 2)
The Water Cycle

❑Water on Earth is continually lost and replenished through the water
cycle (or hydrological cycle).
❑The water moves from one reservoir to another, such as from a river
to the ocean, or from the ocean to the atmosphere via the processes
of evaporation, condensation, precipitation, infiltration, surface
runoff, and subsurface flow.
❑The water cycle involves the exchange of energy, which leads to
temperature changes. These heat exchanges influence climate.

M2 - Natural Systems and Resources (Part 2)
M2 - Natural Systems and Resources (Part 2)
Uses of Water

❑Agriculture
❑It is estimated that 70% of
worldwide water is used for
irrigation.
❑It takes about 2,000 – 3,000 liters
of water to produce food to satisfy
one person’s daily dietary needs.

M2 - Natural Systems and Resources (Part 2)
Uses of Water

❑Industrial
❑It is estimated that 22% of worldwide water is used in industry.
❑Major industrial uses include power generation (hydroelectric), chemical
processing, and in manufacturing as a solvent.

M2 - Natural Systems and Resources (Part 2)
Uses of Water

❑Domestic (Household)
❑It is estimated that 8% of
worldwide water is used for
domestic purposes.
❑These include drinking, bathing,
cooking, toilet flushing, cleaning,
laundry, and gardening.
❑Recreation
❑Recreational water is usually non-
consumptive.
❑The use of water in recreational
activities may reduce the
availability of water for use in
agricultural and domestic
purposes.

M2 - Natural Systems and Resources (Part 2)
Water Stress

❑The supply of water may not be enough for all its uses.
❑Scarcity of water hampers economic development, and human
health and well-being.
❑Several factors affect the availability of water:
❑Population growth
❑The world’s population in 2000 was already 6.2 billion.
❑Water demand will increase and will be one of the main challenges in decades to come.
❑Expansion of business activity
❑Rapid urbanization
❑Urbanization requires a water infrastructure to deliver water to individuals and handle
wastewater.
❑Pollution
❑Climate change

M2 - Natural Systems and Resources (Part 2)
 ENG 2013
Environmental Science and Engineering

M2 – Natural Systems and Resources (Part 3)
Land Resources

❑Land is the most important
valuable resource for
mankind
❑It is composed of organic and
inorganic materials
❑Provides food, fibres,
medicine
❑Source of construction of
materials (wood, sand,
cement, etc.)
❑Source of mineral deposits
❑Acts as a trash bin for solid
wastes produced by society

M2 - Natural Systems and Resources (Part 3)
Land Use in the
Philippines
❑15 million hectares (52.21%) is
forest land
❑14 million hectares (47.79%) is
alienable and disposable
(public domain) land

Land Use

A&D land,
Forest land,
47.79%
52.21%

M2 - Natural Systems and Resources (Part 3)
Ecosystem and Ecosystem Services

❑An ecosystem is a dynamic complex of plant, animal, microorganism
communities and the non-living environment interacting as a
functional unit.
❑Ecosystem services are the benefits that people obtain from these
communities. They include:
❑Provisioning services such as food and fibre
❑Regulating services such as water and nutrient cycling
❑Cultural services such as recreation and spiritual benefits
❑Biodiversity forms an integral component of the ecosystem and
ecosystem services.
❑Rural land plays an essential role in delivering a wide range of
ecosystem services, such as the production of food, fibre, forest
products, and energy, as well as a range of regulating and cultural
services demanded by society.
M2 - Natural Systems and Resources (Part 3)
Land Use Types

❑Wilderness
❑Uncultivated, uninhabited land; inhospitable region
❑National Parks / Wildlife Reserves
❑A scenic or historically important area by the government for the enjoyment
of the general public or the preservation of wildlife.
❑Forests
❑A large area covered chiefly with trees and undergrowth.
❑Wetlands
❑Land consisting of marshes or swamps; saturated land.
❑Agricultural Lands
❑Land used for the production of crops and livestsock
❑Urban Lands
❑Population areas

M2 - Natural Systems and Resources (Part 3)
Land Degradation

❑The growth of the population and
developmental activities have not only
brought about degradation of land but
have also aggravated the pace of
natural forces that cause damage to
land.
❑Effects of land degradation:
❑Soil texture and soil structure is destroyed
❑Loss of soil fertility
❑Loss of valuable nutrients
❑Increase in waterlogging, salinity,
alkalinity and acidity
❑Loss of biodiversity
❑Loss of economic and social benefit

M2 - Natural Systems and Resources (Part 3)
Causes of Land Degradation

❑Population
❑More land is needed for producing food, fibre, and fuel wood.
❑Land is degraded due to exploitation.
❑Urbanization
❑Urbanization reduces the land used for agriculture.
❑Urbanization leads to deforestation, which affects habitats of plants and
animals.
❑Fertilizers and Pesticides
❑Affects soil fertility
❑Causes land pollution
❑Topsoil Damage
❑Increase in food production generally leads to topsoil damage through
nutrient depletion
❑Waterlogging, soil erosion, salination, mineral contamination
M2 - Natural Systems and Resources (Part 3)
Mineral Resources

❑The land is also the source of mineral resources.
❑The Philippines has an abundance of mineral resources.
❑We are the 3rd largest producer of nickel

M2 - Natural Systems and Resources (Part 3)
Classification of Mineral Resources

Minerals

Non-
Metallic Energy
Metallic

Mica,
Non- Coal and
Ferrous Precious Potash,
Ferrous Fossil Fuels
Sulfur salts

Copper, Silver,
Ferrous Lead, Gold,
Bauxite Platinum

M2 - Natural Systems and Resources (Part 3)
Exploitation of Mineral Wealth

❑ Minerals require quite a lot of processing
❑The exploitation of natural resources started to emerge in the 19th
century as natural resource extraction developed.
❑During the 20th century, energy consumption rapidly increased.
❑Today, about 80% of the world’s energy consumption is sustained by
the extraction of fossil fuels, which consists of oil, coal and gas.
❑Another non-renewable resource that is exploited by humans are
subsoil minerals such as precious metals that are mainly used in the
production of industrial commodities.

M2 - Natural Systems and Resources (Part 3)
Mining

❑Mining is the extraction of valuable minerals or other geological
materials from the earth from an ore body, lode, vein, seam, or reef,
which forms the mineralized package of economic interest to the
miner.
❑Ores recovered by mining include metals, coal and oil shale,
gemstones, limestone, and dimension stone, rock salt and potash,
gravel, and clay.
❑Mining is required to obtain any material that cannot be grown
through agricultural processes, or created artificially in a laboratory
or factory.
❑Mining in a wider sense includes extraction of any non-renewable
resource such as petroleum, natural gas, or even water.

M2 - Natural Systems and Resources (Part 3)
Mining

❑Mining of stone and metal has been done since pre-historic times.
❑Modern mining processes involve prospecting for ore bodies,
analysis of the profit potential of a proposed mine, extraction of the
desired materials, and final reclamation of the land after the mine is
closed.
❑The nature of mining processes creates a potential negative impact
on the environment both during the mining operations and for years
after the mine is closed.
❑This impact has led to most of the world's nations adopting
regulations to moderate the negative effects of mining operations.
❑Safety has long been a concern as well, and modern practices have
improved safety in mines significantly.

M2 - Natural Systems and Resources (Part 3)
Effects of Mining

❑Land degradation and deforestation
❑Loss of flora and fauna
❑Overexploitation of earth
❑Water, air, and noise pollution
❑Lowering of ground water table
❑Release of greenhouse gases
❑Production of excess of waste
❑Migration of tribal people
❑Risking of human life

M2 - Natural Systems and Resources (Part 3)
 ENG 2013
Environmental Science and Engineering

M2 – Natural Systems and Resources (Part 4)
Air as a Natural Resource

❑Air is one of the main natural resources
that help sustain all life on Earth.
❑The Earth’s atmosphere is
composed of 78.09% Nitrogen,
20.94% Oxygen, 0.03% Argon, 0.03%
Carbon Dioxide, water vapor, and
other trace gases.
❑The oxygen in the air we breathe in
keeps us alive, and it also performs
many other functions as well.
❑The carbon dioxide we breathe out
as a waste product is used by plants
to produce oxygen through
photosynthesis.
M2 - Natural Systems and Resources (Part 3)
The Atmosphere

❑The atmosphere is the layer of 700 – 10,000 km Exosphere
gases, commonly known as air, that
surrounds the Earth.
❑The atmosphere protects life on
Earth by creating pressure allowing
80 – 700 km
liquid water to exist on the Earth’s Thermosphere
surface, absorbing UV radiation,
warming the surface through heat
retention (greenhouse effect), and
reducing temperature extremes
between day and night.
50 – 80 km Mesosphere

12 – 50 km Stratosphere
0 – 12 km Troposphere

M2 - Natural Systems and Resources (Part 3)
The Atmosphere

❑Exosphere 700 – 10,000 km Exosphere
❑Highest layer. Air is leaking out of the
Earth and into space.
❑Thermosphere
❑Second-highest layer. This is where the
aurora borealis / australis occur.
80 – 700 km
❑Mesosphere Thermosphere
❑Third-highest layer. This is where most
meteors that enter the Earth burn up.
❑Stratosphere
❑Second-lowest layer. This is where the
ozone layer can be found.
❑Troposphere 50 – 80 km Mesosphere
❑This is where 99% of the water vapor can
be found and where weather 12 – 50 km Stratosphere
phenomena occur.
0 – 12 km Troposphere

M2 - Natural Systems and Resources (Part 3)
Wind

❑Wind is caused by the uneven
heating of the Earth’s atmosphere by
the Sun.
❑During the daytime, the air above the
land heats up faster than the air over
water. Warm air expands and rises, and
the heavier, cooler air over the water
rushes in to take its place. This produces
a daytime convection current.
❑In the evening, the air current moves
in the opposite direction. The heat
absorbed by the water during the day
warms the air above it causing the air Sea breeze Land breeze
to rise. Air from over the land which Wind Cycle
has cooled then takes its place.
M2 - Natural Systems and Resources (Part 3)
Wind Energy

❑We can use the wind to produce energy.
❑It is a clean energy source, producing no greenhouse gases.
❑Wind energy is a form of solar energy as winds are produced by the
heat of the sun.
❑Wind energy is a renewable and sustainable energy source.

M2 - Natural Systems and Resources (Part 3)
Air Pollution

❑Air pollution is the presence
of substances in the
atmosphere that are harmful
to the health of humans and
other living organisms, and
cause damage to the climate.
❑Types of air pollutants: Air Pollution from a cooking oven
❑Gases (e.g. ammonia, carbon
monoxide, sulfur dioxide,
CFCs)
❑Particulates, both organic and
inorganic (e.g. dust, pollen)
❑Biological molecules

Beijing air in 2005 after rain (left) and a smoggy day (right)

M2 - Natural Systems and Resources (Part 3)
Effects of Air Pollution

❑Humans
❑Respiratory and renal
problems
❑High blood pressure
❑Problems with the nervous
system
❑Eye irritation
❑Cancer

M2 - Natural Systems and Resources (Part 3)
Effects of Air Pollution

❑Plants
❑Reduced growth
❑Degeneration of chlorophyll
❑Ozone damage

M2 - Natural Systems and Resources (Part 3)
Effects of Air Pollution

❑Environment
❑Acid rain
❑Global warming
❑Ozone depletion

M2 - Natural Systems and Resources (Part 3)
 UST ELECTRICAL ENGINEERING DEPARTMENT
EXPERIMENT LABORATORY GUIDE

EXPERIMENT NO. 5
RLC CIRCUITS

I. OBJECTIVES
1. To apply Ohm’s Law in AC circuits
2. To study the behavior of series and parallel RLC circuit.

II. INSTRUMENTS AND COMPONENTS
AC Power Supply
Lamp, 220 V, 50 W
1 H Inductor
10 μF Capacitor
Connecting Wires

III. PROCEDURE
SERIES RLC CIRCUIT
1. Connect the circuit shown in Figure 5.1. Energize the circuit using 220 V, 60 Hz supply.

Figure 5.1

2. Measure and record the current, IT, the total voltage, VT, the voltage across the series
combination of the lamp and inductor and the series combination of the capacitor and
the inductor, and the voltages across each element.
IT = __________ A
VT = __________ V VR+L = __________ A VL+C = __________ V
VR = __________ V VL = __________ V VC = __________ V

3. Using Ohms’ Law, compute for the equivalent impedance, resistance of the resistor,
reactance of the capacitor, the impedance of the inductor and the impedance of the
series combination of the capacitor and the inductor.
|Zeq| = __________ Ω |ZR+L| = __________ Ω |ZL+C| = __________ Ω
RLAMP = __________ Ω |ZL| = __________ Ω |XC| = __________ Ω

4. Compute the phase angle, θ, of the circuit.
where θ = cos–1[(|ZL+C|2 – RLAMP2 – |Zeq|2)/(–2RLAMP|Zeq|)], θL = 180° – cos–1[(|ZR+L|2 –
RLAMP2 – |ZL|2)/(–2RLAMP|ZL|)] and|XL| = |ZL|sinθL
θ = __________ ° θL = __________ ° |XL| = __________ Ω

5. Compute for the reactances, and the magnitude and the phase angle of the impedance
using the equation |Zeq|∠θ = RLAMP + RL + j|XL| – j|XC|. Use the measured value of the
RLAMP.
where: |XL| = 2πfL, |XC| = 1/(2πfC)
|XL| = __________ Ω |XC| = __________ Ω
|Zeq| = __________ Ω θ = __________ °

Experiment 5 – RLC Circuits Page 1 of 2
 UST ELECTRICAL ENGINEERING DEPARTMENT
EXPERIMENT LABORATORY GUIDE

6. Compute the percent difference between the measured and computed values of the
impedance and the phase angle.
% diff. of Zeq = __________
% diff. of θ = __________

PARALLEL RLC CIRCUIT
7. Connect the circuit shown in Figure 5.2. Energize the circuit using 220 V, 60 Hz supply.

Figure 5.2

8. Measure and record the total voltage, VT, current, IT, the current through the parallel
combination of the resistor and inductor and the current through the parallel
combination of the capacitor and the inductor.
VT = __________ V
IT = __________ A IR+L = __________ A IL+C = __________ A
IR = __________ A IL = __________ A IC = __________ A

9. Using Ohms’ Law, compute for the equivalent impedance, resistance of the resistor,
reactance of the capacitor, the impedance of the inductor and the impedance of the
series combination of the capacitor and the inductor.
|Zeq| = __________ Ω |ZR+L| = __________ Ω |ZL+C| = __________ Ω
RLAMP = __________ Ω |ZL| = __________ Ω |XC| = __________ Ω

10. Compute the phase angle, θ, of the circuit.
where θ = cos–1[(|ZL+C|–2 – RLAMP–2 – |Zeq|–2)RLAMP|Zeq|/–2] , 180° – cos–1[(|ZR+L|–2 –
RLAMP–2 – |ZL|–2)RLAMP|ZL|/(–2)] and|XL| = |ZL|sinθL
θ = __________ ° θL = __________ ° |XL| = __________ Ω

11. Compute for the reactances, and the magnitude and the phase angle of the impedance
using the equation |Zeq|∠θ = RLAMP || (RL + j|XL|) || – j|XC|. Use the measured value
of the RLAMP.
where: |XL| = 2πfL, |XC| = 1/(2πfC)
|XL| = __________ Ω |XC| = __________ Ω
|Zeq| = __________ Ω θ = __________ °

12. Compute the percent difference between the measured and computed values of the
impedance and the phase angle.
% diff. of Zeq = __________
% diff. of θ = __________

END OF EXPERIMENT

Experiment 5 – RLC Circuits Page 2 of 2