Module 1_Introduction PDF

Summary

This document introduces environmental science, defining it as the study of the natural world and human interactions, including living and non-living components. It outlines learning outcomes, the scientific method, and how environmental processes are interconnected.

Full Transcript

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1

Module 1
Env Sci 1 (Environment and Society)

Introduction to
Environmental
Science
Image credit: Google Earth Pro
 Learning Outcomes

!
Distinguish the gaps & overlaps of
Environmental Science with other
disciplines

!
Demonstrate a capacity for the scientific
method in the context of environmental
science

!
Discuss the processes that affect the
environment & the connections among the
processes

3
© C.L.Ringor

Environment
is everything around us. It includes the living and the
nonliving things with which we interact in a complex web
of relationships that connect us to one another and to
the world we live in.

Image credit: IStock by Getty Images
4
https://www.istockphoto.com/
 e. As you’ll learn in reading this book, this field visit http://EnvironmentalScience-Cunningham.blogspot.com.

Environmental
t Is Environmental Science?
Science
ays inhabited two worlds. One is the natural world
s, soils, air, and water that preceded
interdisciplinary study of howus humans
by billions
interact with
hich we are a part. The other is the world of social It
the living & nonliving parts of their environment.
integrates information & ideas from:
rtifacts that we create for ourselves using science,
political organization. Both worlds are essential to
grating them successfully causes enduring tensions.
r people had limited ability to alter their surround-
e power to extract and consume resources, produce
fy our world in ways NATthat threaten
natural sciences - e.g. biology,
both our contin-
SCI chemistry, geology, physics
that of many organisms with which we share the
a sustainable future for ourselves and future genera-
understand something about how our world works,
g to it, and what we can
SOC do tosocial
protect and -improve
sciences it.
e.g. geography,
SCI economics, political science
nt (from the French environner: to encircle or sur-
fined as (1) the circumstances or conditions that
nism or group of organisms, or (2) the complex
ral conditions that affect anhumanities
individual or commu-
- ethics
HUM
ns inhabit the natural world as well as the “built”
social, and cultural world, all constitute impor-
environment (fig. 1.2).
tal science, then, is the systematic study of our Image credit: Cunningham & Cunningham (2012)
FIGURE 1.2 Many kinds of knowledge contribute to solutions
our proper place 5in it. A relatively new field, envi- in environmental science. A few examples are shown.
e is highly interdisciplinary, integrating natural sci-
nces, and humanities in a broad, holistic study of the but not how to persuade factories to install the necessary equipment.
In contrast to more theoretical disciplines, environ- City planners know how to build housing and design safe drinking
mission-oriented. That is, it seeks new, valid, con- water systems, but not how to make them affordable for the poor-
e about the natural world and our impacts on it, but est members of society. The solutions to these problems increasingly
ormation creates a responsibility to get involved in involve human social systems as well as natural science.
thing about the problems we have created. As you study environmental science, you should learn the
shed economist Barbara Ward pointed out, for an following:
er of environmental issues, the difficulty is not to awareness and appreciation of the natural and built environment;. Remedies are now well understood. The problem
knowledge of natural systems and ecological concepts;
socially, economically, and politically acceptable.
ow to plant trees, but not how to establish condi- understanding of current environmental issues; and
h villagers in developing countries can manage the ability to use critical-thinking and problem-solving skills
https://www.dreamstime.com/illustration/ http://www.clker.com/clipart-742551.html
emselves. Engineers know how to control pollution, on environmental issues. animals-earth.html

https://www.123rf.com/clipart-vector/

PTER 1 Goals of
Understanding Our Environment
sustainable_living.html?sti=m1yu968kh7se4dt3m8|
http://www.mhhe.com/cunningham12e
Environmental
Science
(1) to learn how life on the earth has survived and
thrived, (2) to understand how we interact with the
environment, and (3) to find ways to deal with
environmental problems and live more sustainably

6
 Limitations of
Environmental
Science
Scientists cannot prove or disprove anything absolutely,
because there is always some degree of uncertainty in
scientific measurements, observations, & models. They
try to establish that a particular scientific theory has a
very high probability or certainty (typically 90% to 95%)
of being useful for understanding some aspect of the
natural world.

Scientists are human, thus are not totally free of bias
about their own results & hypotheses. The high
standards of evidence required through peer review can
help to uncover or greatly reduce personal bias & expose
occasional scientists who falsify their results.

Many systems in the natural world involve a huge
number of variables with complex interactions. This
makes it too difficult, costly, & time consuming to test
one variable at a time in controlled experiments.
Scientists develop mathematical models that can take
into account the interactions of many variables.

Scientists use statistical tools since not all environmental
changes & events can be measured accurately. They use
statistical sampling & mathematical methods to estimate
measurements.

7
https://www.dreamstime.com/illustration/environmental-science.html

2.1 Understanding What Science Is—and What It Isn’t 25

Understanding Table 2.1

FACTOR IN
KNOWLEDGE IN EVERYDAY LIFE COMPARED WITH KNOWLEDGE IN SCIENCE

EVERYDAY LIFE AND IN SCIENCE

What Science Is Goal
Requirements
To lead a satisfying life (implicit)
Context-specific knowledge; no complex
To know, predict, and explain (explicit)
General knowledge; complex, logical

— and What It
series of inferences; can tolerate ambiguities sequences of inferences, must be precise
and lack of precision and unambiguous
Resolution of questions Through discussion, compromise, consensus Through observation, experimentation, logic

Isn’t Understanding

Validity
Acquired spontaneously through interacting
with world and people; criteria not well defined
Assumed, no strong need to check; based on
Pursued deliberately; criteria clearly specified

Must be checked; based on replications,
observations, common sense, tradition, converging evidence, formal proofs,
How does science differ from other authorities, experts, social mores, faith statistics, logic
ways of knowing? How can we use Organization of knowledge Network of concepts acquired through Organized, coherent, hierarchical, logical;
science to answer practical questions experience; local, not integrated global, integrated
Acquisition of knowledge Perception, patterns, qualitative; subjective Plus formal rules, procedures, symbols,
about our effects on nature & what statistics, mental models; objective
actions we should take to solve Quality control Informal correction of errors Strict requirements for eliminating errors and
environmental problems? making sources of error explicit
Source: Based on F. Reif and J.H. Larkin, “Cognition in Scientific and Everyday Domains: Comparison and Learning Implications,” Journal of
Research in Science Teaching 28(9), pp. 733–760. Copyright © 1991 by National Association for Research in Science Teaching. Reprinted by
Our cultural heritage gives us two ways permission of John Wiley & Sons.

of thinking about the environment: the
Knowledge in everyday life compared with knowledge in science. Image credit: Botkin & Keller (2011).
kind of thinking we do in everyday life & Science as a Way of Knowing in A Closer Look 2.1. One Web site says that some people
the kind of thinking scientists try to do. believe the crop circles are a “spiritual nudge... designed
Science is a process, a way of knowing. It results in con- to awaken us to our larger context and milieu, which is
There are crucial differences between choices, & are not open
clusions, generalizations, to disproof
and sometimes in theo-
scientific Modern
none otherscience
than our does notearth
collective deal with
soul.” Whether or
these two ways of thinking, & ignoring the
riesscientific sense.laws.
and even scientific TheScience
distinction
begins with questions things
not this that
is true,cannot beseem
it does not tested bydisproof.
open to
these differences can lead to invalid arising from curiosity about the natural world, such as: How Science is a such
process of
between a scientific statement & a
many birds nest at Mono Lake? What species of algae live
observation, asdiscovery—a
the ultimate continuing process
whose essence is change in ideas. The fact that scientific ideas
conclusions & serious errors in making nonscientific statement
in the lake? Under is not
what conditions doathey
value
live? purpose of life orWhy
change is frustrating. thecan’t
existence of aon what is
scientists agree
critical decisions about the environment. judgment—there
Modern science does is not
nodeal
implication thatcannot be
with things that supernatural being.
the best diet for people? WhyScience also
is a chemical does dan-
considered
tested by observation, such as the ultimate purpose of life or the gerous in the environment for a while
science is the only “good” kind of
existence of a supernatural being. Science also does not deal
not deal with questions thatand then determined
involve
not to be? Why do scientists in one decade consider forest
We can look at the world from many knowledge.
with questions that involve values, such as standards of beauty values, such disturbances
fires undesirable as standards and inof beauty
a later decadeordecide
points of view, including religious, or issues of good and evil—for example, whether the scenery issues ofare
forest fires good
naturaland
and evil.
in fact important? Are we caus-
at Mono Lake is beautiful. On the other hand, the state- ing global warming or not? And on and on. Can’t scientists
aesthetic, & moral. They are not science Science
ment thatis“more
a process,
than 50% a of way of knowing.
the people who visit Mono just find out the truth and give us the final word on all
because they are based ultimately on Science
Lake findbegins with
the scenery questions
beautiful” arising(discussed
is a hypothesis these questions once and for all, and agree on it?
faith, beliefs, & cultural & personal later)curiosity
from that can be about
tested bythe
public-opinion surveys and can
natural world. The answer is no—because science is a continuing ad-
be treated as a scientific statement if the surveys confirm it. venture during which scientists make better and better ap-
proximations of how the world works. Sometimes changes
8 Disprovability in ideas are small, and the major context remains the same.
Sometimes a science undergoes a fundamental revolution
Here’s the key to science: It is generally agreed today that in ideas.
the essence of the scientific method is disprovability (see Science makes certain assumptions about the natu-
Figure 2.3, a diagram that will be helpful throughout this ral world: that events in the natural world follow patterns
 Science is a process of discovery—a continuing process
whose essence is change in ideas. It is a continuing
adventure during which scientists make better
approximations of how the world works. Sometimes
changes in ideas are small, & the major context remains
the same. Sometimes a science undergoes paradigm
shift.

Science makes certain assumptions about the natural
world: that events in the natural world follow patterns
that can be understood through careful observation &
scientific analysis, & that these basic patterns & the rules
that describe them are the same throughout the
universe.

9

Using Critical
Thinking in
Environmental
Science

"I
analyze information & ideas, judge their
validity, & make decisions

#
distinguish between facts & opinions,
evaluate evidence & arguments, & take &
defend informed positions on issues

$
integrate information, to see relationships,
& to apply your knowledge to dealing with
various problems & decisions

https://talentlens.in/critical-thinking-essence-decisive-mind-works/

10
Question everything & everybody. Be
skeptical. Do not believe everything you
hear & read (including this), without
evaluating the information you receive.
Seek other sources & opinions.

Identify & evaluate your personal
biases & beliefs. Each of us has
biases & beliefs taught to us by our
parents, teachers, friends, role models,
& our own experience. What are your
basic beliefs, values, & biases? Where
did they come from? What assumptions
are they based on? How sure are you
that your beliefs, values, & assumptions
are right & why?

Be open to considering different
points of view. Suspend judgment until questioning. “It ain’t what you don’t be valid but need further testing? Is the
you gather more evidence, & be willing know that gets you into trouble. It’s what information based on a few isolated
to change your mind. Recognize that you know for sure that just ain’t so.” stories or experiences or on carefully
there may be a number of useful & controlled studies that have been
acceptable solutions to a problem, & Find out how the information related reviewed by experts in the field
that very few issues are either black or to an issue was obtained. Are the involved?
white. There are trade-offs involved in statements you heard or read based on
dealing with any environmental issue. firsthand knowledge & research or on Question the evidence &
hearsay? Are unnamed sources used? conclusions presented. What are the
Be humble about what you know. Is the information based on reproducible conclusions or claims based on the
Some people are so confident in what & widely accepted scientific studies or information you’re considering? What
they know that they stop thinking & on preliminary scientific results that may evidence is presented to support them?

11

Does the evidence support them? Is Expect & tolerate uncertainty. Do not believe everything you read
there a need to gather more evidence to Recognize that scientists cannot on the Internet. Evaluating information
test the conclusions? Are there other, establish absolute proof or certainty on the Internet is one of the best ways
more reasonable conclusions? about anything. However, the results of to put into practice the principles of
science have varying degrees of critical thinking. Use & enjoy the
Try to uncover differences in basic certainty. Internet, but think critically & proceed
beliefs & assumptions. Many with caution.
disagreements are based on different (& Check the arguments you hear &
often hidden) basic assumptions read for logical fallacies & debating Become a seeker of wisdom, not a
concerning how we look at & interpret tricks. Here are six of many examples vessel of information. Many people
the world around us. Uncovering these of such debating tricks: (1) attack the believe that the main goal of their
basic differences can allow the parties presenter of an argument rather than education is to learn as much as they
involved to understand one another’s the argument itself; (2) appeal to can by gathering more & more
viewpoints & to agree to disagree about emotion rather than facts & logic; (3) information. The primary goal is to learn
their basic assumptions, beliefs, or claim that if one piece of evidence or how to sift through mountains of facts &
principles. one conclusion is false then all other ideas to find the few nuggets of wisdom
related pieces of evidence & that are the most useful for
Try to identify & assess any motives conclusions are false; (4) say that a understanding the world & for making
on the part of those presenting conclusion is false because it has not decisions. Facts & numbers are useful
evidence & drawing conclusions. been scientifically proven. (Scientists only to the extent that they lead to an
What is their expertise in this area? Do never prove anything absolutely, but understanding of key ideas, concepts,
they have any unstated assumptions, they can often establish high degrees of connections, & scientific laws & theories
beliefs, biases, or values? Do they have certainty.); (5) inject irrelevant or
a personal agenda? Can they benefit misleading information to divert attention
financially or politically from acceptance from important points; & (6) present only
of their evidence & conclusions? Would either/or alternatives when there may be
investigators with different basic a number of options
assumptions or beliefs take the same
data & come to different conclusions?

12
Science and Values
Precautionary Principle

Deciding what to do about an environmental
problem involves both values & science. We must
choose what we want the environment to be. But to
make this choice requires knowing the scientific
data & understanding its implications. What we
choose should not only be dictated by our values.

Science & values come to the forefront when we
think about what action to take about a perceived
environmental problem for which the science is only
partially known. For this reason, in 1992 the Rio
Earth Summit on Sustainable Development listed as
one of its principles what we now call the
Precautionary Principle —when there is a threat
of serious, perhaps even irreversible, environmental
damage, we should not wait for scientific proof
before taking precautionary steps to prevent
potential harm to the environment.

The Precautionary Principle requires us to think
ahead & predict potential consequences before they
occur. It is a proactive, rather than reactive, tool—
that is, we can use it when we see real trouble
coming, rather than reacting after the trouble arises.

13
© CLRingor

Solar Energy

Sustainability: The
Environmental Goal
The variety of life on Earth has been sustained for
at least 3.8 billion years in the face of catastrophic
changes in environmental conditions. Three major
interdependent natural factors have played the
key roles in the long-term sustainability of life on
this planet - scientific principles of
sustainability:
Image credit: Miller & Spoolman
(2016).

(1) Dependence on solar energy. The sun’s
input of energy, called solar energy, warms the
planet & provides energy that plants use to
produce nutrients, the chemicals necessary for
their own life processes & for those of most
other animals, including humans. The sun also
powers indirect forms of solar energy such as
wind and flowing water, which we use to
produce electricity.

https://simple.wikipedia.org/wiki/ https://www.amwater.com/tnaw/water-information/water-
Photosynthesis learning-center/the-water-cycle/
14
 Biodiversity

(2) Biodiversity (short for biological diversity) is
the variety of genes, organisms, species, &
ecosystems in which organisms exist & interact.
The interactions among species, especially the
feeding relationships, provide vital ecosystem
services & keep any population from growing too
large. Biodiversity also provides countless ways FIGURE 1.2 Three
Solar Energy of sustainability b
for life to adapt to changing environmental has sustained a hug
conditions, even catastrophic changes that wipe the earth for 3.8 bi
out large numbers of species. drastic changes in e
conditions (Concep

(3) Chemical cycling or nutrient cycling is the
circulation of chemicals necessary for life from the
environment (mostly from soil & water) through

© Cengage Learning
organisms & back to the environment. The earth Image credit: Miller & Spoolman (2016).
receives a continuous supply of energy from the
sun, but it receives no new supplies Chemical of life- Cycling Biodiversity
Chemical Cycling
supporting chemicals. Through their complex
interactions with their living & nonliving
environment, organisms cycling. The earth receives
must continually a continuous supplyinofnature,Sustainability Has Certain Key Components
recycle
energy from the sun, but it receives no new supplies
the chemicals they need in order to survive. This
of life-supporting chemicals. Thus through their
waste = useful
Sustainability, the central integrating theme of this book,
means that there is littlecomplex
waste interactions
in nature, other resourceshas several critical components that we use as subthemes.
with their living and nonliving
than in the human world, because the wastes &
environment, organisms must continually recycle the One such component is natural capital—the natural
decayed bodies of anychemicals
organismthey become
need in order to survive. This means resources and ecosystem services that keep us and other
species alive and support human economies (Figure 1.3).
nutrients or raw materialsthatfor other
there organisms.
is little waste in nature, other than in the
human world, because the wastes and decayed bodies Natural resources are materials and energy in na-
of any organism become nutrients or raw materials for ture that are essential or useful to humans. They are often
other organisms. In nature, classified as inexhaustible resources (such as energy from
the sun and wind), renewable resources (such as air, water,
waste = useful resources
topsoil, plants, and animals) or nonrenewable or depletable
Ecology and environmental science reveal that interde- resources (such as copper, oil, and coal). Ecosystem ser-
pendence, not independence, is what sustains life and allows it vices are processes provided by healthy ecosystems that
to adapt to a continually changing set of environmental support life and human economies at no monetary cost to
conditions. Many environmental scientists argue that un- us. Examples include purification of air and water, re-
derstanding this interdependence is the key to learning newal of topsoil, nutrient cycling, pollination, and pest
how to live more sustainably. control.
15
Chemical Cycling Biodiversity
6 CHAPTER 1 ENVIRONMENTAL PROBLEMS, THEIR CAUSES, AND SUSTAINABILITY

cycling. The earth receives a continuous supply of Sustainability Has Certain K
Copyright 2016 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). energy from the sun, but it receives no new supplies
Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it.
of life-supporting chemicals. Thus through their Sustainability, the central integrating
complex interactions with their living and nonliving has several critical components that
environment, organisms must continually recycle the One such component is natural
While environmental scientists
90446_ch01_002-023.indd 6 search for scientific solutions to chemicals they need in order to survive. This means resources and8:13
8/13/14 ecosystem
AM services th
problems, social scientists are looking for economic & political that there is little waste in nature, other than in the species alive and support human eco
Natural resources are materia
solutions. The search for solutions often involves conflicts. human world, because the wastes and decayed bodies Resources Are Inexhaustible, Renewable,
of any organism become nutrients or raw materials or Nonrenewable
for ture that are essential or useful to hu
Dealing with such conflicts often involves making trade-offs, or classified as inexhaustible resources (
other organisms. In nature, A resource is anything that we can obtain from the envi-
compromises, whether as a group or as an individual. Our ronment to meet theoursun and
needs andwind),
wants. renewable resourc
Some resources,
waste = useful resources
study of environmental problems, proposed solutions, & trade- such as surface topsoil, plants,
water, trees, and animals)
and edible or are
wild plants, nonr
Ecology and environmental science reveal thatdirectly
interde-availableresources (suchresources,
for use. Other as copper,suchoil, and co
as petro-
offs has led us to propose three social science principles of
Left: Minerva Studio/Shutterstock.com. Center: mikeledray/Shutterstock.com. Right: Kali Nine LLC/istockphoto.com.

leum,itminerals,
pendence, not independence, is what sustains life and allows wind,are
vices andprocesses
underground water, become
provided by hea
sustainability: to adapt to a continually changing set of environmental useful to us only with some effort and technological
support life and human economies a
ingenuity.
conditions. Many environmental scientists argue that un- us. Examples
Resources include
can be classified purification o
as inexhaustible,
(1) Full-cost pricing (from economics): Many economists derstanding this interdependence is the key to learning renewable,
ECONOMICS
newal or of topsoil, nutrient
nonrenewable cycling,
(exhaustible)
how to live more sustainably. (Figure 1.6). Solar energy is called an inex-
control.
recommend to include the harmful environmental & health haustible resource because its continuous
Full-cost pricing

costs of producing & using goods & services in their market supply is expected to last for at least 6 bil-
lion years until the sun dies. It also pro-
prices—a practice called full-cost pricing. This would give 6 CHAPTER 1 ENVIRONMENTAL PROBLEMS, THEIR CAUSES, AND SUSTAINABILITY
vides us with inexhaustible wind and
consumers better information about the environmental impacts flowing water that we use to produce
rat to
s

electricity. A renewable resource is
ion
Wi

of their lifestyles, & it would allow them to make more informed
ure nsi S
ge bility
PO in r

fut espo THIC
n-w

Copyright 2016 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due toone that
electronic can
rights, somebethirdreplenished bysuppressed
party content may be nat- fro
LIT esu

ne

choices about the goods & services they use.
Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if su
ural processes within hours to
ICS lts

E

centuries, as long as we do not
R

use it up faster than natural
(2) Win-win solutions (from political science): We can learn90446_ch01_002-023.indd 6 processes can renew it. Exam-
ples include forests, grasslands,
to work together in dealing with environmental problems by fishes, fertile topsoil, clean air,
recognizing our interdependent connections with others & and freshwater. The highest rate
at which we can use a renewable
with our life-support system. This means shifting from a win- resource indefinitely without re-
lose approach based on competition & dominance of other ducing its available supply is called its
sustainable yield.
FIGURE 1.5 Three social science principles of sustainability can help us make
humans & of ecosystems to win-win solutions that are based
Social Science Principles of Sustainability
a transition to a more environmentally and economically sustainable future.

on compromise in light of our interdependence & that benefit
both people & the environment Image credit: Miller & Spoolman (2016).
Left: Carole Castelli/Shutterstock. Center: Alexander Kalina/Shutterstock.

(3) A responsibility to future generations (from ethics): We
should leave the planet’s life-support systems in at least as
good a condition as that which we now enjoy, if not better, for
future generations.

16

Inexhaustible Renewable Nonrenewable (Exhaustible)
 Geosphere

Atmosphere

3.1 Basic Systems Concept 45

Biosphere
steady-state system, the inputs (of anything of interest) If the water input equals the water output and evaporation
are equal to the outputs, so the amount stored within is not considered, the water level in the lake does not
the system is constant. An idealized example of a steady- change, and so, in regard to water, the lake is in a steady
state system is a dam and lake into which water enters state. (Additional characteristics of systems are discussed
from a river and out of which water flows (Figure 3.4). in A Closer Look 3.1.)

A CLOSER LOOK 3.1
Hydrosphere Earth as a System
Simple Systems
A system is a set of components, or parts, that function
together as a whole.
A simple way to think about a system is to view it as a series Input (I ) Output (O)
of compartments (also called “reservoirs,” and we will use
these terms interchangeably), each of which can store a certain (a) Compartment X
amount 17of something you are interested in, and each of which
Humanosphere
receives input from other compartments and transfers some of e.g., water
from a spigot
e.g., water
in a bathtub
e.g., water
down the drain
its stored material to other compartments (Figure 3.6a).
The general equation is The change in the amount stored in (∆S ) of X is the
difference between the input I and the output O
mathematically, and t is the unit time say an hour,
I = O ± ∆S day or year.
∆St=It-Ot or It=Ot_∆St
where I is input into a compartment; O is output, and ∆S is

Basic Systems
change in storage. This equation defines a budget for what is
No change Tree farm A simple way to think about a system is to view it
being considered. For example, if your checking account has (b)
$1,000 in it (no interest rate) and you earn $500 per month
in size of that plants as a series of compartments or reservoirs, each of
reservoir one tree for
which can store & receive from other reservoirs &

Concepts
at the bookstore, input is $500 per month. If you spend $500 every one cut
Input equal to Output transfer some of its stored material to other
per month, the amount in your account will be $1,000 at the
Steady-state reservoirs. Image credit: Botkin & Keller (2011).
end of the month (no change in storage). If you spend less
than $500 per month, your account will grow (+∆S). If you
spend more than $500 per month, the amount of money in Reservoir
yourAaccount
system can be(-∆open
will decrease S). or closed. In an (c) is Use of
fossil fuels
reduced
open system,water
An environmental some energy
engineer could oruse material
this kind of
systems diagram
(solid, (Figure
liquid, or3.6a)
gas) to plan
movesthe size of the
into orvarious
out of Input less than Output
dams to be built on the Missouri River, taking into account Negative change
the the system.
desired total storage a closed
In among the dams system, noand
(Figure 3.4)
the such transfers
role of each take place.
dam in managing the river’sFor
flowour
(refer
Reservoir Pollution of
back to the opening case study and also see Figure 3.7). In
purposes, a materially closed system
Figure 3.7, the amount stored in a dam’s reservoir is listed as
(d) grows lake with
pesticides
Xn,is oneX isinthewhich
where amountno matter
of water storedmoves
and n is theinnumber
&
Input greater than Output
outcompartment.
of the of the system, although
(In this case the dams are energy
numbered & in Positive change
order from upstream to downstream.) Water flows from the F IGU RE 3.6 (a) General equation for ways in which a compart-
information can move across the
environment—tributaries, watersheds, and direct rainfall— stability. Such a system has a constant
ment of some material can change. (Source: Modified from P.R.
equal to the outputs, so the amount
intosystem’s boundaries.and eachEarth is a to the Ehrlich, A.H. Ehrlich, and J.P. Holvren, Ecoscience: Population,
each of the reservoirs, is connected stored within the system is constant. A
condition, and if it is disturbed from that
Resources, Environment, 3rd ed. [San Francisco: W.H. Freeman,
materially
adjacent reservoirsclosed system
by the river. (for
Finally, all all Missouri’s
of the practical 1977].) Row (b) represents steady-state conditions; rows (c) and
water flows into the Mississippi, which carries it to the Gulf condition, it returns to it once the
(d) are examples of negative and positive changes in storage. steady state (dynamic equilibrium),
purposes).
of Mexico. disturbing factor is removed. also called balance of nature, is
For this water-flow system, we can make a complete flow and do a scientific analysis of many environmental problems,
seldom attained or maintained for very
Systems
diagram. This kindrespond to inputs
of diagramming helps us to&think
have about so you will find such diagrams throughout this book.
long. Rather, systems are characterized
Populations, species, ecosystems, &
outputs. For example, increasing Earth’s entire biosphere are dynamic not only by human-induced
greenhouse gases (input) in the lower systems, always changing & always disturbances but also by natural
atmosphere is the primary cause of the requiring change. disturbances. Disturbances due to
present global warming (output). natural events, are necessary for the
With few exceptions, all real systems maintenance of those systems. Systems
Systems maybe static or dynamic. A that we deal with in the environment are change naturally. If we are going to
static system has a fixed condition & open to the flow of matter, energy, & manage systems for the betterment of
tends to remain in that exact condition. information. An important distinction for the environment, we need to gain a
A dynamic system changes, often open systems is whether they are better understanding of how they
continually, over time. An important kind steady-state or non-steady-state. In change.
of static system is one with classical a steady-state system, the inputs are

18
 Systems of 3.1 Basic Systems Concept 49

Change ORV use

The output of a system also depends on
how long, on average, an input will
remain in a reservoir — average Loss of vegetation
residence time. This has important
implications for environmental systems. +
A system such as a small lake with an
inlet & an outlet & a high transfer rate of + Erosion, gullies, ruts
water has a short residence time for
water. That makes the lake especially
vulnerable to change because change
can happen quickly. But, any pollutants Widening of ORV paths
soon leave the lake. In large systems
with a slow rate of transfer of water,
such as oceans, water has a long
residence time. Such systems are much Example of a positive feedback. Off-road vehicles (ORV) may
Increase in cause positive feedback to soil erosion. ORV
erosion
(a) erode the soil & uproot plants. Without vegetation, the soil erodes faster, exposing even more soil (positive
less vulnerable to quick change. feedback). As more soil is exposed, rainwater carves out ruts & gullies (more positive feedback). Drivers of
However, once polluted, large systems = positive
ORV then avoid the ruts & gullies by driving on feedback
adjacent sections thatloop
are not as eroded, widening paths &
with slow transfer rates are difficult to + (b) erosion because they
further increasing erosion (more positive feedback). The gullies themselves increase
clean up. concentrate runoff & have steep side slopes. Once formed, gullies tend to get longer, wider, & deeper,
FIGURE
causing additional 3.10
erosion How
(even moreoff-road
positive feedback). (a) create
vehicles Image credit:positive feedback
Botkin & Keller (2011).
on soil erosion (b) and (c).
When the output of a system (or a
reservoir in a system) affects its input,
state systems can remain in a constant further increase in output. Also called a
feedback occurs. There are two kinds
condition. Positive feedback occurs “vicious cycle,” it is destabilizing.
of feedback: negative & positive. increases air and water pollution, disease, crime, and dis-
when an increase in output leads to a
Negative feedback is self-regulating, c