Introduction to Environmental Science PDF

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This document provides an introduction to environmental science, discussing its multidisciplinary nature and the interactions between living organisms and their environment. It covers topics such as biotic and abiotic factors, ecosystem structure, and the importance of environmental science in daily life.

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Introduction to
Environmental Science

Environmental science is a multidisciplinary field that studies how living organisms
interact with their environment. It encompasses the natural world, human impact
on the environment, and the search for solutions to environmental problems.

Psyche Karren Ann O. Jondonero
Definition and Scope of Environmental Science

Environmental science encompasses the study of the Earth's atmosphere, hydrosphere, lithosphere, and biosphere. It investigates the
investigates the interrelationships between living organisms and their physical surroundings.

Biotic Factors Abiotic Factors Human Impact
Includes living organisms, such as plants, Includes non-living components like air, Examines how human activities affect the
plants, animals, bacteria, and fungi. air, water, soil, sunlight, and temperature. environment, including pollution,
temperature. deforestation, and climate change.
Importance of Environmental Science in
Daily Life
Environmental science is crucial for understanding and addressing the environmental challenges. It helps in
making informed decisions about people’s day to day life, from choosing sustainable products to
conserving resources.

1 Clean Water 2 Healthy Air
Ensures access to safe and clean water for Protects air quality, reducing respiratory
water for drinking, agriculture, and problems and improving overall health.
industry.

3 Climate Change Mitigation 4 Resource Management
Develops strategies to reduce greenhouse Promotes sustainable use of natural
greenhouse gas emissions and mitigate the resources, ensuring their availability for
mitigate the effects of climate change. for future generations.
change.
Interdisciplinary Nature of Environmental Science

Environmental science integrates knowledge from various disciplines, including biology, chemistry, physics, geology, and social
sciences. This interdisciplinary approach is essential for understanding complex environmental issues.

Biology Ecology, biodiversity, population dynamics

Chemistry Pollution, water quality, chemical cycles

Physics Energy flow, climate change, atmospheric science

Geology Soil science, land use, natural resource management

Social Sciences Environmental policy, economics, ethics, and human behavior
Ecosystem Structure
An ecosystem is a complex web of living organisms and their
physical environment. It is a self-sustaining unit that
encompasses all interactions between living and non-living
components.
Levels of Ecological Organization

Ecology is organized into a hierarchical structure, with each level building upon the previous one. This organization
helps scientists understand the complexity of ecological systems and how they function as a whole.

1 Species (Individual)
A single organism, the basic unit of ecology.

2 Population
A group of individuals of the same species living in the same area.

3 Community
All the populations of different species living and interacting in a particular area.

4 Ecosystem
A community of organisms interacting with their physical environment.

5 Biosphere
The sum of all ecosystems on Earth.
Abiotic Factors and Their Influence
Abiotic factors, such as temperature, light, water, and nutrients, play a crucial role in shaping the
distribution and abundance of organisms within ecosystems. Each species has specific tolerances and
requirements for these factors, determining its habitat and range.

1 Temperature 2 Light
Affects metabolic rates, enzyme activity, and Provides energy for photosynthesis and
survival. influences plant growth.

3 Water 4 Nutrients
Essential for all living organisms and Support plant growth and influence the
influences plant distribution. productivity of ecosystems.
Limiting Factors
Too much or too little of any abiotic factor can limit or prevent growth
of a population, even if all other factors are at or near the optimal
range of tolerance.

1 Sunlight 2 Water
Insufficient sunlight can Lack of water can lead to
limit plant growth and dehydration and death,
photosynthesis. particularly in arid
environments.

3 Nutrients 4 Temperature
Deficiencies in essential Extreme temperatures,
nutrients, such as whether too hot or too
nitrogen and phosphorus, cold, can negatively
can inhibit plant growth impact organism survival.
and development.
Range of Tolerance

Optimal Range Zone of Stress Zone of Intolerance
Conditions where organisms thrive and Conditions where organisms can Conditions that are too extreme for
reproduce successfully. survive but experience physiological organisms to survive.
stress and reduced growth or
reproduction.
Biotic Components
Producers Consumers Decomposers
Autotrophic organisms that create their Heterotrophic organisms that obtain Organisms that break down dead organic
own food through photosynthesis, such obtain energy by consuming other organic matter and recycle nutrients
as plants and algae. organisms, including herbivores, nutrients back into the ecosystem, such
carnivores, and omnivores. such as fungi and bacteria.
Producers

Photosynthesis Energy Foundation
Producers use sunlight, water, and Producers form the base of the food
carbon dioxide to create their own food food chain, providing energy for all other
food (glucose) and oxygen as a other organisms in the ecosystem.
byproduct.

Habitat Provision Oxygen Production
Producers create habitats for other Producers release oxygen into the
organisms, providing shelter and nesting atmosphere, which is essential for the
nesting sites. the survival of most organisms.
Consumers

Herbivores Carnivores Omnivores
Primary consumers that feed on Secondary consumers that feed Consumers that feed on both
producers, such as deer, rabbits, on other animals, such as lions, plants and animals, such as bears,
and insects. wolves, and sharks. pigs, and humans.
Decomposers

Role Description

Nutrient Recycling Break down dead organic
matter, releasing nutrients
back into the soil for
producers to use.

Waste Removal Decompose waste products,
preventing the accumulation
of harmful substances in the
environment.

Soil Formation Contribute to the formation
of fertile soil by breaking
down organic matter into
smaller particles.
Detritus feeders, or detritivores
: feed on the wastes or dead bodies of other organisms
Ecosystem Function
Ecosystem function describes the interactions between living
organisms and their environment. It's a complex web of processes
that keep ecosystems healthy and resilient.
Energy Flow and Nutrient Cycles in
Cycles in Ecosystems
Ecosystems function through the interconnected processes of energy flow and nutrient cycling.
cycling. Energy flows through an ecosystem in a linear fashion, while nutrients are recycled
recycled continuously.

1 Producers
Plants capture sunlight and convert it into chemical energy through
photosynthesis.

2 Consumers
Animals obtain energy by consuming producers or other consumers.

3 Decomposers
Break down dead organisms and waste products, releasing nutrients back into the
back into the ecosystem.
Food Chain and Food Web
Food Chain Food Web

A food chain is a linear sequence of organisms where each organism A food web is a complex interconnected network of food chains,
consumes the one below it, representing a single pathway of energy chains, depicting the intricate relationships and energy flow among
transfer. among multiple organisms.
Ecological Efficiency
Energy Transfer Trophic Levels
Only about 10% of the energy from The number of trophic levels in a
from one trophic level is in a food chain is limited by the
transferred to the next, with the the amount of energy available at
the rest lost as heat or used for available at the base, hence the
metabolism. the pyramid shape.

Ecological Implications
The low efficiency of energy transfer explains why ecosystems have fewer top
fewer top predators compared to lower trophic levels.
Biogeochemical Cycle

1 Essential Nutrients 2 Reservoirs
Nutrients like carbon, nitrogen, Nutrients are stored in different
phosphorus, and sulfur are different reservoirs like the
essential for life and cycle through atmosphere, soil, water, and living
the ecosystem. living organisms.

3 Processes 4 Human Impact
Nutrient cycling involves biological, Human activities like deforestation,
biological, chemical, and physical deforestation, agriculture, and
physical processes that move pollution can disrupt nutrient
nutrients between different cycling, leading to imbalances in
reservoirs. in the ecosystem.
Water Cycle

Evaporation
Water evaporates from bodies of water and soil, turning into water vapor.

Condensation
As water vapor rises, it cools and condenses into clouds.

Precipitation
Water falls back to Earth as rain, snow, sleet, or hail.
Alteration of Water Cycle by Humans

withdrawal of large quantities of freshwater
from streams, lakes, and underground sources
clearing vegetation from land
increasing flooding
 Carbon Cycles through
the Biosphere

- the process that moves carbon between

plants, animals, and microbes; minerals

in the earth; and the atmosphere
Carbon Cycle

Carbon moves from the atmosphere to
plants.
Carbon moves from plants to animals.
Carbon moves from plants and animals
to soils.
Carbon moves from living things to the
atmosphere.
Carbon moves from fossil fuels to the
atmosphere when fuels are burned.
Carbon moves from the atmosphere to
the oceans.
 Nitrogen Cycles through
the Biosphere

- Biogeochemical process which
transforms the inert nitrogen in the
atmosphere to a more usable form
for living organisms.
Nitrogen Cycle

a. Nitrogen fixation,
b. Nitrification,
c. Assimilation,
d. Ammonification and
e. Denitrification
Nitrogen Cycle

1 Nitrogen Fixation
Nitrogen gas is converted into ammonia by nitrogen-fixing bacteria.

2 Nitrification
Ammonia is oxidized to nitrite and then nitrate by nitrifying bacteria.

3 Assimilation
Plants and other organisms absorb nitrate for growth.

4 Ammonification
Decomposers break down organic matter, releasing ammonia back into the soil.

5 Denitrification
Denitrifying bacteria convert nitrate back into nitrogen gas, returning it to the atmosphere.
Phosphorus Cycle

Rock Cycle Plant Uptake
Phosphorus is released from rocks Plants absorb phosphorus from the soil
through weathering and erosion. and water.

Food Web Decomposition
Phosphorus moves through the food Decomposers release phosphorus back
food web as organisms consume other back into the soil and water.
other organisms.
Phosphorus Cycles through the Biosphere

1. Reservoir – erosion transfers phosphorus to
water and soil; sediments and rocks that
accumulate on ocean floors return to the
surface as a result of uplifting by geological
processes

2. Assimilation – plants absorb inorganic PO43-
(phosphate) from soils; animals obtain
organic phosphorus when they consume
plants and other animals

3. Release – plants and animals release
phosphorus when they decompose;
animals excrete phosphorus in their waste
products
The phosphorus cycle, with
major harmful human impacts
shown by red arrows.
Sulfur Cycle
Atmospheric Sulfur Soil Sulfur
Sulfur dioxide in the atmosphere Sulfur is present in soil as sulfates,
can react with water to form which are taken up by plants.
sulfuric acid, contributing to acid
rain.

Human Impact
Burning fossil fuels releases sulfur dioxide into the atmosphere, leading to
acid rain and other environmental problems.
 Sulfur Cycles
through the Biosphere

1. Reservoir – underground in rocks and
minerals, volcanoes, in ocean
sediments, and atmosphere

2. Assimilation – plants absorb sulfate
(SO4) from soils; animals obtain organic
sulfur when they eat plants and other
animals

3. Release – plants and animals release
sulfur when they decompose;
Overview of Environmental Issues and
Challenges
Environmental science addresses a wide range of issues that threaten our planet's health, from pollution and climate change t o
climate change to biodiversity loss and resource depletion.

Climate Change
Global warming, rising sea levels, extreme weather events.

Pollution
Air, water, soil pollution, impacting human health and ecosystems.

Deforestation
Loss of forests, habitat destruction, and biodiversity decline.

Biodiversity Loss
Extinction of species, disruption of ecological balance, and ecosystem services decline.
Biodiversity: Definition,
Importance, and Threats
Biodiversity refers to the variety of life on Earth, encompassing all living organisms and
their ecosystems. Biodiversity is essential for maintaining ecosystem services, providing
resources, and promoting resilience.

Ecosystem Services Food and Medicine
Pollination, pest control, water Source of food, medicine, and other
purification, and climate regulation. valuable products.

Resilience Threats to Biodiversity
Ability of ecosystems to withstand Habitat loss, pollution, climate
disturbances and adapt to change. change, invasive species, and
overexploitation.
Conservation of Biodiversity
Conservation of biodiversity aims to protect and manage species, habitats, and ecosystems. It involves various approaches, from establishing protected areas to
promoting sustainable practices.

Habitat Protection Species Conservation International Cooperation Sustainable Practices
Establishing protected areas and Focusing on threatened or Promoting environmentally
managing existing ecosystems to endangered species through captive Global collaboration among responsible practices in agriculture,
conserve biodiversity. breeding, habitat restoration, and governments, organizations, and forestry, and other industries.
anti-poaching efforts. individuals to address transboundary
environmental issues.
Types of Natural Resources:
Renewable vs. Non-renewable

Natural resources are materials and energy sources that exist in nature and are used
by humans. Renewable resources can be replenished naturally over time, while non-
renewable resources are finite.

1 Renewable Resources 2 Non-renewable
Resources Resources
Solar energy, wind energy, Fossil fuels (coal, oil, natural
hydropower, biomass, and gas), minerals, and metals.
timber.
Sustainable Use of Resources
Sustainable use of resources aims to meet present needs without compromising the ability of future generations to meet their own needs. It
emphasizes resource conservation, efficiency, and waste reduction.

Renewable Energy Sustainable Urban Planning Sustainable Agriculture
Shifting from fossil fuels to renewable Designing cities that are compact, walkable, Adopting practices like crop rotation, organic
energy sources like solar, wind, and hydro walkable, and promote public farming, and reduced pesticide use to
hydro power. transportation, reducing resource protect soil health and biodiversity.
consumption and emissions.