Introduction to Ecology 2024 PDF

Summary

This document provides an introduction to ecology, outlining topics such as ecology and ecosystems, energy flow in ecosystems, and pollution in aquatic environments. It is likely a lecture presentation or course materials for an environmental science class or biology course.

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An Introduction to Ecology

Env.E. 101
Fall 2024
Outline

Ecology and ecosystems

Energy flow in ecosystems

Pollution in Aquatic Environments
Ecology
Ecology – science dealing with interactions
between organisms and the environment
– These interactions determine distribution of
organisms and their abundance
– Plants and animals in their physical and chemical
environment make up an ecosystem.
Ecosystems
Ecosystems are communities of organisms
that interact with one another and with
physical environment including sunlight,
rainfall, and soil nutrients as well as chemical
environment.
Ecosystem is somewhat more technical term
for “nature”.
Structure of Ecosystem

Abiotic components: Non-living things

Biotic components: Living things
Structure of Ecosystem
Biotic components:
Primary producers – Plants, algae etc.
(autotrophs)
All convert light energy into metabolic energy
Consumers – Primary, secondary etc. (Macro consumers)
(heterotrophs)
Primary consumers (herbivores) feed on primary producers
(Plant eaters).
Higher organisms are carnivores (meat eaters).

Decomposers – bacteria, fungi (Micro consumers)
(heterotrophs)
They break down the dead bodies (detritus) and release simple
substances usable by the producers.
 © 2011 Cengage Learning Engineering. All Rights Reserved.

Source: Introduction to Environmental Engineering SI; Vesilind, Morgan, Heine
Pyramid Effect
Structure of Ecosystem
Abiotic components:
Inorganics – Nutrient elements C, H, N, S, O, P, Mg, K,
Na etc.
Recycle in the environment and are available to biotic
components.
Organics – Cellulose, lignin, proteins, carbohydrates,
lipids etc.
Physical Conditions – Temperature, pH, currents etc.
Ecosystems
Ecosystems are continually regulated by checks and
balances. i.e. there are forces and counterforces in
order to compensate every phenomena.

e.g. CO2 remains fairly
constant in the biosphere
thanks to green plants
utilizing this gas. CO2 fixed
by plants is oxidized back
to CO2 (by fossil fuel
combustion)
Ecosystems
Ecosystems are continually regulated by checks and
balances. i.e. there are forces and counterforces in
order to compensate every phenomena.

e.g. CO2 remains fairly
constant in the biosphere
thanks to green plants
utilizing this gas. CO2 fixed
by plants is oxidized back
All living systems to resist change and to
to CO2 (by fossil fuel
remain in a state of equilibrium. But, human
combustion)
upset the balance…
Ecosystems function thru:

1. Energy flow between
trophic levels

1. Recycling of
nutrients (mass flow)
Energy and Trophic Levels

– Part of sun energy hits the surface of the earth
– Of this, 1-2 % is converted to useful metabolic
energy
Energy and Trophic Levels
Thermodynamic Law:
1. You cannot create or destroy energy
but you can only transfer it from one
form to another
2. During transfer or conversion, a
portion will be lost as heat. The rest
will be available for work.

– Part of sun energy hits the surface of the earth
– Of this, 1-2 % is converted to useful metabolic
energy
 Energy flow in a food chain

Sun (e.g. 1000 J)
The transfer of
98% energy lost
food energy from (e.g. 7 J maintenance)
Producer (e.g. 12 J) (e.g. 5 J new tissue)
plants, ultimately
to higher animals 90% energy lost
by way of eating Primary consumer (e.g. 0.5 J)
and being eaten. 90% energy lost
Secondary consumer (e.g. 0.05 J)
90% energy lost
Tertiary consumer (e.g. 0.005 J)
 © 2011 Cengage Learning Engineering. All Rights Reserved.

Energy flow in a food chain

Source: Introduction to Environmental Engineering SI; Vesilind, Morgan, Heine
Energy Flow in Ecosystems
(via Food Chain)
The flow of energy maintains order and life.

Ecosystems maintain a high state of internal
order or a condition of low entrophy.

For example: an animal takes in chemical
potential energy for food, large part of this energy
is dissipated and a small fraction (10%) is
converted into new protoplasm.
Roles of Organisms
Organisms can be either producers or
consumers in terms of energy flow through an
ecosystem.
Producers convert energy from the
environment into carbon bonds (plants,
algea, deep-sea bacteria) (autotroph)
Consumers get their energy from the
carbon bonds made by the producers
(heterotroph)
Bioaccumulation and Biomagnification
Bioaccumulation build
up of substances (e.g.
DDT) in the tissues of
organisms

Biomagnification
cumulative build up of
substances sequentially
through a food web by
a series of
bioaccumulation
Food chain & food web
Biomagnification of DDT in a Marine Ecosystem

(0.04 ppm)

Source: Introduction to Environmental Engineering SI; Vesilind, Morgan, Heine
World War II - DDT

It was used in the second
half of World War II to
control malaria and typhus
among civilians and troops.
DDT
Paul Hermann Müller was
DDT is an effective pesticide given 1948 Nobel Prize in
medicine for his discovery
DDT was used for about 20 years,
of the high efficiency of
then banned
DDT as a contact poison
But, the body of every people still has against several insects"
DDT
Agricultural pesticides…
Arsenic and other chemicals had also been used as
agricultural pesticides
Mercury, cadmium may also accumulate

As a result of high concentration of chemicals, many
bird populations are going extinct.

The greater the biodiversity, the greater stability in
ecosystem

PP1 X
PP2 PP3 PP4 …
Recycling of Nutrients in
Ecosystems
Biogeochemical cycles

Living organisms require 30-40 elements
Finite supply
Utilization of these needs to be
compansated
Cycles make the elements available for
reuse by transforming and recirculating
them thru atmosphere, hydrosphere,
litosphere and biosphere.
Biogeochemical cycles
Types:

Gaseous nutrient cycles
Sedimentary nutrient cycles
Gaseous nutrient cycles
Nutrient reservoir : the atmosphere

There is little or no loss of the nutrient
element.

Typical cycles: “C, O, N” cycles
Sedimentary nutrient cycles
Nutrient reservoir : sedimentary rocks
Considerable loss of the nutrient elements
(sedimentary loss in deep-sea)
Typical cycles: “P, S” cycles
 Carbon Cycle
CO2 in the air
Respiration
Respiration
Photosynthesis
Respiration

Decomposers Death Plants

Death

Animals Eating
Nitrogen Cycle

79% of the atmosphere is
made up of nitrogen gas Nitrogen is
essential for all
N2 organisms to make
very few organisms can proteins
extract it from the air
Nitrogen Cycle

N2
Photochemical,
industrial
Biological fixation
fixation Eating

NO3-
Death and
decay Denitrification

NO3-
 Phosphorus Cycle

P is a vital component P is essential for all
of organisms
DNA, RNA & ATP
Phosphorus Cycle
 Sulphur Cycle

S is a vital part of
protein
(-SH-thiol group) Both gaseous and
soluble forms
S is essential for all
organisms
Sulphur Cycle
 © 2011 Cengage Learning Engineering. All Rights Reserved.

Water Cycle

Water budget P=I+E+T+R
Source: Introduction to Environmental Engineering SI; Vesilind, Morgan, Heine