Lesson 1 and 2 Merged.pdf

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Conceptual Framework of
HUMAN ECOLOGY

To understand Human Ecology is to
take the risk of stepping out of our
disciplinal anchors. – MET
Mendoza
Maria Emilinda T. Mendoza
DSDS, CHE, UPLB
HUMAN ECOLOGY IN THE CONTEXT OF THE
ACADEMIC AND SCIENTIFIC COMMUNITY
Human Ecology is an Emergent Science
– Human Ecology is relatively recent compared to the more
classical disciplines considered to be its growth points.
– While its disciplinal growth points can currently boast of
hundreds of years of discourse and development, Human
Ecology as a formal science in its own right can only claim
as far as the 1920s when the term human ecology was
first used as a sociological concept by Burgess, McKenzie
and Park of the Chicago School (Young, 1974; Sorlin, 1986)
and the mid-1930s when Sir Arthur Tansley formally
defined ecosystem as a concept
HUMAN ECOLOGY IN THE CONTEXT OF THE
ACADEMIC AND SCIENTIFIC COMMUNITY
Human Ecology is an Emergent Science
– This also means that it is a field of study that is still
emerging and continues to transform as a
response to human problems and needs as
humans – whether as individuals or within the
context of their social groups, engage the natural
environment.
HUMAN ECOLOGY IN THE CONTEXT OF THE
ACADEMIC AND SCIENTIFIC COMMUNITY
Human Ecology is a Meta-science
– HE goes with other forms of scientific activity thus
providing other more direct disciplines access to
issues and problems which are difficult to handle
by just a single discipline.
– just as mathematics is a meta-discipline in
chemistry as a direct science, human ecology may
serve as a meta-discipline for its more classical
growth points such as sociology and biology to be
relevant in current problematiques
HUMAN ECOLOGY IN THE CONTEXT OF THE
ACADEMIC AND SCIENTIFIC COMMUNITY

Human Ecology is a Trans-discipline
– a trans-discipline is a field of study that continuously
undergoes transformation, one that goes beyond
disciplinary mind-sets into a re-conceptualization of
phenomena, problems, goals, and approaches. It
accepts complexity and pays attention to dynamic
interactions (in space and time) between natural and
human-made systems. Participation of end-users is
essential, as is gender analysis. Accountability to end-
users becomes intrinsic to the process. It enhances
the possibilities for sustainable development (Peden,
1999).
HUMAN ECOLOGY IN THE CONTEXT OF THE
ACADEMIC AND SCIENTIFIC COMMUNITY
Human Ecology is a Trans-discipline
– Human Ecology can be described as a trans-
discipline, i.e., it is a discipline that reticulates
other disciplines for purposes of approaching real
interaction, without assuming a stance of
superiority that it can change these disciplines.
– The transdisciplinarity of Human Ecology enables it
to transcend conventional single and
multidisciplinal approaches but does not replace
them.
 Figure 4.
Human Ecosystem
Human Ecosystem
Framework
(Machlis, Force,
Critical Resources and Dalton, 1997)

Biophysical
Resources

Social System

Socioeconomic Social Institutions Social Cycles
Resources

Social Order
Cultural
Resources
 Environmental
Integrity

ENVIRONMENT
HUMAN Stewardship (Biological,
Empowered SYSTEMS Physical, Food and
Organizations and (Individual, Social, Nutrition
Family, Cultural,
Institutions Security
Community) Provision Political,
Economic
Technological)

Developed
Human
Potentials
CONCEPTUAL FRAMEWORK OF HUMAN ECOLOGY (CHE, UPLB, 2008)
Explaining the CHE Framework
The outer circle drawn in solid lines is meant to
represent the goal of a well-balanced human
ecological system: that of achieving total human
ecological security.
The conspicuousness of the goal of a functional
human-ecological system is necessary to drive home
the point that the study of human ecology cannot be
divorced from current issues and problems impinging
upon human ecological systems. This makes the
study of human ecology problem- and solution-
oriented.
Explaining the CHE Framework
Especially, but not necessarily exclusive to the
Philippine context, the quest for human ecological
security is currently represented primarily by
– 1) the tasks of achieving food and nutrition security,
– 2) the insurance of environmental integrity,
– 3) the provision of opportunities, venues and services for
the full development of human potentials, and
– 4) the efforts toward well-capacitated, responsive and
empowered organizations and institutions through which
societal aspirations for such security can be planned,
operationalized and implemented.
– The arrangement of these objectives in circular form is to
conceptualize such as fluid and subject to temporal and
spatial variability.
Explaining the CHE Framework
By choosing to focus on the human ecological
system, Human Ecology contends that human
systems can never be divorced from an
environmental context.
– While a human system at any level of complexity can be
conceptually isolated from its context with its temporal and
spatial character, its full definition and analysis shall always
necessarily include its environment.
– This environment can be represented through a variety of
biophysical, socio-cultural, eco-political and technological
variables. Moreover, this environment will always have a
dynamic relationship with human systems.
Explaining the CHE Framework
The dynamism of the human ecological
system is importantly reflected by the solid
arrows showing the characteristic interaction
between humans and their environment.
– Because human ecological system variables are in a
state of interaction, the dynamism of the system is a
constant.
– In general, the permeability and dynamic nature of
the human ecological system is represented by the
broken line of the inner circle.
Explaining the CHE Framework
To ensure the attainment of its objectives, the
human-environment interaction which defines the
character of a specific human ecological system is
importantly typified by steward-like human behavior
and decisions.
– This necessitates that the human concept of the
environment is one where the latter, in its entirety, is seen
as a provider for the sustenance of human being – singly or
as an aggregate unit.
– Equally important is the human perspective of this
environment as a subject and recipient of sustainable use
and careful, nurturing human behavior.
Explaining the CHE Framework
Thus, a human system (such as a family or a
community) is in interaction with a specific variable
of the environment (such as land) as represented by
a family and/or communal land use.
In the same manner, a social institution (such as a
local government unit) is in interaction with a rapidly
changing economic variable (such as price of basic
commodities), as exemplified by policy reforms
and/or refinements as a form of adaptation.
Explaining the CHE Framework
Human Ecology as a perspective and as a disciplinal
endeavor takes as its unit of analysis the systemic
nature of human-environment interaction.
– This means considering the structural nature of a human
ecological phenomenon while focusing on the functional
and dynamic character of this phenomenon exemplified by
the interaction between humans, either as individuals or
as social groups, and environmental variables.
– The identification, understanding and rethinking of forms
of human-environment interaction which provide for the
dynamic nature of any human ecological system are clearly
the task of Human Ecology.
Maraming
Salamat
Po!
 ECOLOGY and
HUMAN ECOLOGY

HUME 100
aProf. Gillian D. Consignado
ECOLOGY
 ECOLOGY
1. “Oikos” – house
“Logos” – study of

study of how the occupants of the environment
interact (Haeckel, 1869 in Miller, 1975)
ECOLOGY
German zoologist Ernst Haeckel
“science of the habitat”
(Lawrence 2001, 675).
2.

The scientific study
of relationships of
living organisms
with each other &
their environment.
“No living organism exists in isolation.”
3.
The study of the
structure & function of
nature.
-(Odum, 1974)

Humankind as part of nature.
4.

The study of the total flows of chemical
elements, energy & water w/in a
defined area, the interactions of these
flows with the populations w/in & the
effects of all human’s activities on
cycle flows & populations.
▪ Relationships & Interactions
 Over the Years
Charles Elton, British ecologist
(1927) – “scientific natural history”
concerned with sociology and
economics of animal
Charles Elton

Frederick Clements (1905)
“the science of the community”

Karl Friedrichs (1958)
“ the science of the environment”
Frederick Clements
Ecology is an integrative science.

❑ Integrative science
▪ relationships and interactions of all living organisms with each
other and with their environment
▪ diversity and variety among populations
▪ maintenance of biodiversity, including laws governing
communal living and sharing of resources
Major features of
all life

✔ Interdependence
✔ Diversity
✔ Vulnerability
 ECOLOGY and
HUMAN ECOLOGY

HUME 100
aProf. Gillian D. Consignado
 HUMAN
ECOLOGY
 DEVELOPMENT OF
HUMAN ECOLOGY
-Ellen Swallow Richards

-In 1892 she used Haeckel’s term
“oekology” to mean the science of the
conditions of the health and well-being
of everyday human life, elaborated as
human ecology in 1907.
HUMAN ECOLOGY
1.
It is the field of study in which the
principles of ecology are applied
to man and his interactions with
the environment.
2.
The study of human
interrelationships and
interactions with the
environment.
3. The study that seeks to
understand human and
his/her problems by
studying individuals and
populations as biological
entities profoundly
modified by culture.
4.

The study of
ecosystems as they
affect and are
affected by human
beings.
5.

It is the study of those settings
mainly settlements, inhabited by
those organisms called humans.
❖ Individual
❖ Family
❖ Community
An interdisciplinary approach
to understanding human-
environmental systems.

It seeks to combine
understanding of the biophysical
realities of human existence (such
as dependence on natural
resources) with the social and
Dr. Robert Dyball
psychological dimensions of
Australia National University
human health and well-being.
 Human Ecology is all
about
Relationships
Connections
✔ humans & their environment
✔ actions & consequences
✔ changes & adaptations
Human Ecology
takes its
disciplinal root
from Ecology and
other disciplines.
 Ecology Human Ecology
Focus: Focus:
Relationships Interactions of
of living & the social
non-living environment
entities with with the
their physical
environment environment
 Ecology Human Ecology
Role: Role:
Shaped by Shaper of and
their shaped by
environment their
environment
 Ecology Human Ecology
Disciplinary Disciplinary
base: base:
Biophysical Social
sciences sciences
Biophysical
sciences
Ecology
 is an
interdisciplinary
science. ☺
 HUMAN ECOLOGY

Concerned with the processes that
limit and change this system over
time (Sustainability?)
Concerned with the social
dimensions of current or proposed
alternate arrangements (Fair, Just, &
Ethical Issues?)
 HUMAN ECOLOGY

Fundamental concern on
ecological sustainability and
social justice
Improvement of what, by
what means, and in whose
interest
 HUMAN ECOLOGY

Ultimately, Human Ecology is motivated by care and
concern for the future. It seeks to imagine what it
might be to live and do well in a humane, sustainable
and worthwhile world and to invite and enthuse
broader community commitment to work towards
realizing those futures.
 Environmental
Integrity

ENVIRONMENT
(Biological,
HUMAN Stewardship
Physical,
Empowered SYSTEMS Social, Food and
Organizations (Individual, Cultural, Nutrition
Political,
and Institutions Family, Economic
Security
Provision
Community) Technological)

Developed
Human
Potentials
CONCEPTUAL FRAMEWORK OF HUMAN ECOLOGY (CHE, UPLB, 2008)
Why
is there a need for the
human ecological
perspective?
 Stewards
not
Masters

When we realize that we are Stewards Not
Masters of creation then our natural resources
will be wisely utilized for masters get what they
want at any cost but Stewards carefully weigh
gains against the loss such ‘gains’ may cause.
Respecters not Defilers of Life

When we recognize that
there are other lives than our lives in this
planet
And that our lives and their lives are
interconnected Artwork by: Suzanne Duranceau

Then we learn to be responsible in how we
treat our natural resources
For wanton destruction of the environment is
disrespect for life and is sheer selfishness.
 Defenders
not mere Dependents

When we grasp the fact that we are
Defenders and not mere Dependents of
nature then we will do whatever is necessary
to conserve our natural resources
and prevent all forms of environmental abuse
for it is one best way of giving back to life’s
sustaining source.
 “To understand Human Ecology is to take the
risk of stepping out of our disciplinal anchors.”
– MET Mendoza

The heart of
change is a
change of heart.
– John Kotter
 BASIC
HUME 100
CONCEPTS
IN ECOLOGY
5 Levels of Ecological
Organization
1. Organisms
-Anything that is living
-Occupies a place of area called
habitat
-Has a niche : the resources it
needs to survive
 Ancient
bristlecone
pine trees
2. Populations
- Group of interbreeding
organisms living within a
specific area
- Es. A flock
of birds
Characteristics:
-Size
-Extends through time,
contraction and
expansion
3. Community

A number of populations of
different organisms that occupy
& interact in a given area
Desert community
4. Ecosystem
- Any defined area of
nature that includes
living organisms &
non-living substances
interacting with each
other
 4. Ecosystem

A major unit of Ecology
Eco- relates to the environment
System- a collection of related parts that
function as a unit (Smith and Smith, 2002)
 Forest
ecosystem
Components of
an Ecosystem
 Structural components
1. Non-living (abiotic) components
2. Living (biotic) components

Types of relationship

a. Predator-prey interaction – one organism serves as the
food source for another
Can this be beneficial to the prey population?
b. Commensalism – relationship between species that is
beneficial to one, but neutral or of no benefit to the other

c. Mutualism – beneficial to both organisms; the interaction
is necessary for the survival and growth of each species

d. Parasitism – interaction between two species in which one
benefits at the expense of the other organism (parasite-host)
 Relationships
It grows as a small seedling
then grows larger enough. It
starts to snuff out the host
plant. By that point it can stand
on its own and the host plant
decays, leaving a hollowed out
center.

Strangler Fig
 Kinds of Biotic Components
1. Producers – auto-trophs/ self-productive
2. Consumers (Macro-consumers) – herbivores,
carnivore and omnivores
3. Decomposers (Micro-consumers) –
saprotrophs
 Functional
Components
Functional Components
a. Energy Flow – For life to exist, the
earth must constantly receive inputs of
energy from the sun and make outputs of
heat energy which are passed to outer
space.
Functional Components
b. Food Chain – It is a series of feeding
relationships between organisms that
shows who eats whom.
Functional Components
c. Ecological Diversity – A
generalization that has grown from the
studies of biotic communities is that
species diversity enhances stability in an
ecosystem.
Biodiversity – nature’s richness of life
forms which include the number and
degree of genes species and the
ecosystem in a given assemblage
Importance: ethical and aesthetic;
economic; essential services provided by
natural ecosystem
Stratification - Refers to separations
between organisms in space or time

An ecosystem can be stratified in space
either vertically (layers) or horizontally
(concentric circles).
 Spatial Stratification
Forest roof

Middle layer

Lower layer

Forest floor
Spatial Stratification
Functional Components
d. Evolution
happens over a long period of time which
entails the changes in the population’s
collective genetic material, natural
collection, nutrition, adaptive traits,
differential reproduction
Functional Components
e. Ecological Succession
process whereby an ecosystem
changes from simple community
into a complex and relatively stable
one
Ecological Succession
Functional Components

f. Ecological Control or Cybernetics

regulating itself based on information
feedback; concept of limit range
 What can ecosystems provide?

Schematic representation of the ecosystem services selected by UNEP, as categorized
in the Millennium Ecosystem Assessment
Supporting services: ecosystem services that are
necessary for the production of all other ecosystem
services
nutrient dispersal and cycling, seed dispersal, primary
production

Provisioning services: products obtained from
ecosystems
food (including seafood and game), crops, wild foods,
and spices, water, minerals (including diatomite)
pharmaceuticals, biochemicals, and industrial products
energy (hydropower, biomass fuels)
Regulating services: benefits obtained from the regulation of
ecosystem processes, carbon
sequestration and climate regulation, waste decomposition
and detoxification, purification of water and air,
crop pollination, pest and disease control

Cultural services: nonmaterial benefits people obtain from
ecosystems through spiritual enrichment, cognitive
development, reflection, recreation, and aesthetic experiences
cultural, intellectual and spiritual inspiration,
recreational experiences (including ecotourism)
scientific discovery
Natural Ecological Cycle
(Geologic Cycle)

1. Tectonic Cycle
2. Hydrological Cycle
3. Biogeochemical Cycle
4. Rock Cycle
5. Ecosphere

The grand system that
includes all life forms and
the areas on/in which
they exist
Biosphere

Hydrosphere

Atmosphere

Lithosphere
 “Human Ecology”
by Robert Dyball

An excerpt from the forthcoming Berkshire Encyclopedia of
Sustainability Volume 4: Natural Resources and Sustainability.

Available at www.berkshirepublishing.com.

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H
 Human Ecology

Human ecology is an interdisciplinary approach to that rely on multifaceted analyses. Sustainability problems
understanding human-environmental systems. The field typically involve a degree of scientific uncertainty, in that
seeks to combine understanding of the biophysical reali- it is not always possible to gauge accurately the status of
ties of human existence (such as dependence on natural the key environmental variables that have to be managed.
resources) with the social and psychological dimensions For example, it is hard to assess the carbon stored in agri-
of human health and well-being. cultural landscapes under different management regimes,
yet this could be a key element in promoting sustainable

H uman ecology focuses on understanding humans and farming practices. In addition, sustainability problems

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their environments as parts of a whole. Although the often have no clear boundaries and cut across institutional

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field predates current debates about sustainability, it shares and jurisdictional boundaries, including different depart-

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concern for the limited capacity of the Earth to meet the mental responsibilities or state and national borders, such
demands that humans are placing on it. Human ecology

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as when atmospheric pollution from a smokestack in one
is also concerned with ethical questions about how fairly state causes acidification in the forests of its neighbor. In

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environmental resources are shared among people and many cases the ultimate cause of a problem is at a great dis-
other living things, and identifying the rights and wrongs

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tance in time or space from its effect. For example, a con-

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of existing situations and proposed alternatives. Where sumer’s choice of coffee bought from a local supermarket
the human-environment system is changing in ways that

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can affect, for better or worse, the environmental health of
cause problems for people, human ecology focuses on what a coffee plantation landscape in a distant country. Many

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is ultimately driving that change, and the consequences. problems are the unforeseen and unintended consequences
By seeking the ultimate, rather than immediate, causes of human activity that made perfect sense at the time. Irri-

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of change, human ecology typically locates the sources gating a property to increase food yields makes sense, as

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of many problems in aspects of the dominant culture, its does building freeways to relieve traffic congestion. Yet an
attendant values, and resulting human behavior. The chal- unintended consequence of irrigation might be to mobilize
lenge then is to identify interventions that will result in naturally occurring salts in the soil and eventually render
improved environmental outcomes and that are fair and it useless for farming; similarly, freeways can make private
acceptable to the people who are affected. Human ecolo- vehicle travel choices more attractive and result in even
gists are then typically committed to act as change agents greater congestion as more people adopt this method of
by seeking interventions that improve the health and well- transport. Problems can even defy definition. Building
being of people in a humane and sustainable manner. a hydropower station on a river might be the solution to
a problem of renewable energy generation but the cause
Human Ecology and Sustainability of a problem for river ecology and fish populations. This
complexity is compounded as individuals and groups pro-
Human ecology is able to make a valuable contribution to mote often-conflicting options for intervention to improve
understanding and improving situations that are labeled a situation, and various judgments about the desirability of​
as sustainability problems because it provides approaches proposed solutions.

308
 Human Ecology 309

With sustainability problems, pathways to improvement seeks to provide a conceptual framework for research and
will often involve changes to human attitudes and behav- learning that combines knowledge about what is and what
iors as much as they will involve new or changing tech- needs to be done, with understanding about what motivates
nology. Certainly technology can improve the efficiency and enables individuals and societies to act on the basis of
with which an environmental resource is extracted and that knowledge. Human ecologists are agents of change,
managed and reduce the unit cost of the good produced, seeking to help societies achieve humane and sustainable
but improving efficient supply cannot always keep up with futures.
total increasing demand. Modern jet aircraft can be more
efficient as measured by the energy cost of each passenger Ecology and Human Ecology
transported per mile, but with soaring passenger numbers
the total energy cost of the sector will increase. Expecting Human ecology has its origins in ecology more gener-
changes in people’s behavior requires ethical considerations ally. The term ecology was originally coined by the Ger-
of justice and fairness in terms of how people are engaged man zoologist Ernst Haeckel in 1866 to mean, loosely,
in the development of proposed solutions and, when costs the “science of the habitat” (Lawrence 2001, 675). At this
are involved, how the burden of those costs is distrib- basic level, human ecology can be thought of as the study
uted. This ethical concern may also extend to species other of the environmental conditions in which human beings
than humans. With its concern for the ethical dimension, developed, and the relationship of humans to the ecosys-
human ecology has a normative dimension that tems that support them and which they affect.
other sciences often lack or downplay. The same principles apply to the ecol-
Human ecology’s concern for the ogy of any species, but in the case
sociocultural dimensions of sus- of humans, the number of humans
tainability problems is coupled with on the planet, their presence in
the recognition that ecosystems almost all terrestrial ecosystems,
have a finite capacity to service the and their impact on the planet is
demands human place on them. If largely the product of the evo-

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human demands on environmental lution of human capacity for

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resources exceed the rate at which culture. If success is mea-
those resources are naturally sured by sheer numbers and

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replenished, then the resource ability to colonize nearly

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will inevitably be exhausted. At every environment on the

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best, for very large stocks, this planet, then culture was an
point of exhaustion may be far evolutionary advantage.

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off into the future, which might The need to take cul-

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allow postponing the inevitable ture and its effects seriously

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requirement for human behav- makes the study of the ecol-
ioral change. A similar principle ogy of humans different from

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applies to pollution: problems the ecology of other animals.

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arise when rates of accumulation Other species exhibit behav-

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exceed the natural capacity of the ioral adaptation to their sur-
ecosystem to absorb pollutants. The roundings, but for humans
unequivocal evidence is that human sociocultural adaptation is the
use of key resources is now rapidly prime mechanism for responding
approaching their limits, and many people to environmental change. Humans
already do not have access to sufficient resources can learn and adapt their behavior based on
to maintain minimal standards of health and well-being. information provided by other humans, in stories passed
The complex nature of sustainability problems means from generation to generation and enshrined in enduring
that they are best tackled using integrative, holistic social institutions. Humans have a highly developed abil-
approaches that combine traditional disciplinary knowl- ity to imagine consequences of future action, although they
edge with other insights into the human condition, people’s do not necessarily act to avoid those consequences. Artistic
beliefs and values, and their aspirations and motivations. creativity enables the celebration of traditional ways of liv-
Human ecology draws these insights from the social sci- ing and the imagination of alternative futures. Imagination
ences, as well as the humanities; arts and design; and lay, and inventiveness also allow humans to develop tools and
community, and nonacademic knowledge bases. The field technologies that extend their capacity to access resources
310 Berkshire Encyclopedia of Sustainability: Ecosystem Management and Sustainability

from the environment and to rapidly change the efficiency such as urban design and regional planning, these pro-
with which they can convert resources into a service. These grams brought together a range of disciplines to apply
characteristics of cultural adaptation, social and individ- their unique insights jointly to a given problem. Pragmati-
ual learning, institutional arrangements, art and creativity, cally focused, these approaches collected insights from the
imagination, and technology, while not necessarily unique contributing disciplines, without defining a unifying
to humans, are developed to highly complex levels in them. framework. The frameworks, assumptions, and method-
ologies are not transformed through their interactions with
Development of Human Ecology other disciplinary experts. Nevertheless, this multidisci-
plinary approach continues to be practiced by those who
As human ecology developed out of ecology and the natu- place a premium on maintaining forums in which different
ral sciences, it followed a number of different trajectories. disciplines can share their insights.
Current academic programs using the term human ecology
often exhibit different characteristic concerns depending Interdisciplinary Human Ecology
on which of these pathways they followed.”
Ellen Swallow Richards, born in Massachusetts in Human ecologists have sought to define a genuinely inter-
1842, is one pioneer of the discipline. Richards was the first disciplinary field of study, in which the understanding
woman graduate of the Massachusetts Institute of Technol- achieved is more than the sum of the contributing parts.
ogy (MIT), graduating with a bachelor of science degree in The challenge is to retain the power of disciplinary thinking
chemistry in 1873. She also obtained a master’s degree, but while avoiding the partiality of such work. Interdisciplin-
the award of a PhD was beyond what MIT at that time was ary human ecology tackles complex sustainability problems
prepared to confer on a woman. Her disciplinary expertise with approaches that have rigor but are not rigid. It may use
was in industrial chemistry, but she had broader interests in a systems-based framework, which enables consideration of
the social movements of the day, including women’s issues the influence and constraints of both social and biophysical
and progressive social change more generally. In 1892 she drivers of change. The system in question, its boundaries,
used Haeckel’s term oekology to mean the science of the component parts, and its dynamics are defined by partici-
conditions of the health and well-being of everyday human

t
pating stakeholders. Such an approach enables the integra-
life, elaborated as human ecology in 1907. But the biologi-

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tion of the diverse values, desires, and needs of the human
cal scientists resisted extending the concept of ecology to actors with the capacity of the environment.

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include social dimensions, and the term home economics was

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adopted in its place. Human ecology programs that derive As a college dedicated to human ecology, the College
from this lineage are still common in the United States

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of the Atlantic in Bar Harbor, Maine, exemplifies the
today, typified by programs in education and childhood graduate attributes typical of a student of human ecology.

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studies, nursing, family and community well-being, and It bases its curriculum on the following characteristics:
local applied policy issues.

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Today the study of human ecology may be defined by Be creative: use the imaginative and inventive powers of
the interests, methods, and intellectual domain of particu- the human mind to tackle sustainability problems with

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lar disciplines. One strand of human ecology as a field of original and adaptable approaches. This commitment to

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study arose within the sociology department at the Uni- creativity has to include a willingness to take risks and
versity of Chicago in the 1920s. In this school of thought,

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sometimes fail, so long as failure is acknowledged and
ecological terms from the biosciences are applied to social learned from.
change processes, using concepts such as competition, suc- Think critically: reflect critically on the partiality of
cession, web of life, and mutual interdependence. Versions information, including the unavoidable prejudicial ele-
of human ecology also developed within other social sci- ments that arise from human habits, biases, and assump-
ence disciplines, such as geography, anthropology, and tions. This ability to think critically includes reflection
ethnology, but beyond contesting ownership of the name, on one’s own limitations and preconceptions.
these versions of human ecology have little in common. Engage with community: involve individuals, commu-
Growing environmental awareness in the 1960s gave nities, and institutions in the design and implementation
rise to a different approach to human ecology. This mul- of solutions to their problems. This includes a willing-
tidisciplinary human ecology recognized the limited ness to learn from their knowledge and traditions. It
contribution that single disciplines could, by themselves, also requires participants to connect theory and practice.
make to understand the complexity of human-induced eco- Communicate: communication is understood to be pro-
logical problems. Typically arising in applied professions cesses of learning and not merely the transmission of
 human ecology 311

knowledge from one party to the other. Communication a whole-of-system approach to the material and energy
can include artistic and motivational elements. flows of Hong Kong and the sociocultural drivers of those
Integrate elements: think comprehensively about situa- flows. The study was a seminal work in research into urban
tions as wholes. The characteristic behavior of the whole metabolism and is an exemplar of research incorporating
emerges from, but cannot be reduced to, the interactions both the quantifiable and qualitative dimensions of sus-
of the parts. Sustainability is a description of the behav- tainability. In the twenty-first century, ANU continues to
ior of a system of interest to an individual or group as it be a leader in the field of human ecology through its teach-
changes or remains constant over time. ing and research program, as well as through open discus-
Practice interdisciplinarity: recognize the strength and sion at the Human Ecology Forum.
depth of disciplinary thinking and the crucial contri- The aforementioned College of the Atlantic (COA) is
bution it can make to solving problems, while being entirely dedicated to the study of human ecology. COA
aware of its partiality. Combining different contribu- places great emphasis on developing an applied approach
tions within suitable conceptual frameworks is crucial through working collaborations with local and interna-
to creating the new knowledge needed to tackle sustain- tional communities. Over the years a number of initiatives
ability problems. originating from student projects have, through commu-
As an evolving approach to defining and investigating nity engagement, been adopted in practice, such as the
its subject matter, human ecology may appear to have a Maine legislature’s adoption of beverage recycling as a con-
complex and occasionally contradictory history. This same sequence of work conducted by COA students. The college
diversity, however, prepares human ecology to contrib- offers ongoing demonstration projects of applied human
ute new approaches to complex and previous intractable ecology in areas of collaborative decision making, environ-
problems mental design, conservation ecology, ecological education,
green business, and watershed-based regional planning.
COA has also received numerous awards for institutional
Human Ecology in Action resource management, campus buildings, and leadership
in its commitment to carbon neutrality.

t
Many university-based human ecology programs around Human ecology research focuses on a variety of develop-

f
the world are sponsoring research and publishing that con- ment issues. Researchers from the Department of Human
tinue to define the field and also lead to public sustain- Ecology at the University of Tokyo have been

a
ability initiatives. In addition, organizations involved in interdisciplinary research

r
such as the Society for Human Ecology, into relationships between human

D
the Commonwealth Human Ecology and environmental health in rap-
Council, and the German Society for idly developing Asian countries.

e
Human Ecology bring practitioners Studying rural areas, research

l
together to advance the field teams have tracked changes

p
As early as 1972, following a to a broad range of indica-
meeting organized by the Com- tors of human well-being,

m
monwealth Human Ecology Council such as income, labor

a
(CHEC) in Hong Kong, a group arrangements, food and

S
of researchers, primarily based in nutrition, exposure to
the Human Ecology program of various chemical com-
the Australian National Uni- pounds, and health.
versity (ANU), undertook a Policy interventions
major study of the city of designed to inf luence
Hong Kong and its popu- national development can
lation. Published under be initially successful, but
the auspices of the United then after a delay, negative
Nations Educational, Sci- consequences appear. An
entific and Cultural Orga- example is rising food
nization (UNESCO) as production: this may
The Ecology of a City and Its result in improved nutri-
People (Boyden et al. 1981), tion, but a consequent ris-
this landmark study applied ing chemical burden in the
312 Berkshire Encyclopedia of Sustainability: Ecosystem Management and Sustainability

local environmental eventually leads to potential risks for Further Readings
community health. The relationship between chemical Agyeman, Julian; Bullard, Robert D.; & Evans, Bob. (Eds.). (2003). Just
levels and community health is nonlinear, however, with sustainabilities: Development in an unequal world. Cambridge, MA:
MIT Press.
different individuals and communities affected to differ-
Boyden, Stephen. (2003). The biology of civilisation: Understanding human
ent degrees for a range of reasons detectable only at the culture as a force in nature. Sydney: University of New South Wales Press.
local scale. Interdisciplinary human ecological research can Boyden, Stephen; Millar, Sheelagh; Newcombe, Ken; & O’Neill,
suggest ways that policy interventions can be targeted to Beverley. (1981). The ecology of a city and its people: The case of Hong
Kong. Canberra, Australia: Australia National University Press.
community involvement to achieve a balance of technologi-
Brown, Valerie A.; Harris, John A.; & Russell, Jacqueline Y. (Eds.).
cal and social initiatives that can produce more consistently (2010). Tackling wicked problems through the transdisciplinary imagina-
positive outcomes. tion. London: Earthscan.
Chapin, F. Stuart, III; Kofinas, Gary P.; & Folke, Carl. (Eds.). (2009).
Principles of ecosystem stewardship: Resilience-based natural resource
Future Directions management in a changing world. New York: Springer.
Chivian, Eric, & Bernstein, Aaron. (Eds.). (2008). Sustaining life: How
Research in human ecology has been hampered by the human health depends on biodiversity. Oxford, UK: Oxford University
field’s nontraditional nature, including perceptions that it is Press.
Dauvergne, Peter. (2008). The shadows of consumption: Consequences for the
not a proper science. It has been challenging to find fund- global environment. Cambridge, MA: MIT Press.
ing bodies willing and able to support interdisciplinary Dyball, Robert, & Newell, Barry. (2012). Understanding human ecology.
research or journals willing to publish the results. Because London: Earthscan.
it is an awkward fit within the traditional departmental Hulme, Mike. (2009). Why we disagree about climate change: Understanding
controversy, inaction, and opportunity. New York: Cambridge
structures of the university system, recognition of merit University Press.
and pathways for career development have been limited. Keen, Meg; Brown, Valerie A.; & Dyball, Rob. (Eds.). (2005). Social
Although these barriers continue to exist, there is growing learning in environmental management: Towards a sustainable future.
recognition of the need for approaches like human ecology London: Earthscan.
Lawrence, Roderick J. (2001). Human ecology. In Mostafa Kamal Tolba
to tackle sustainability challenges. The Ecological Soci- (Ed.), Our fragile world: Challenges and opportunities for sustainable
ety of America’s (ESA) Planetary Stewardship Initiative development (Vol. 1, pp. 675–693). Oxford, UK: Encyclopedia of Life

t
(Power and Chapin 2009) is devoted to fostering interdis- Support Systems (EOLSS) Publishers.

f
ciplinary collaboration and defining the scientific needs to Merchant, Carolyn. (2007). American environmental history: An introduc-
tion. New York: Columbia University Press.
encourage sustainable social and ecological change. ESA’s

a
Midgley, Gerald. (2000). Systemic intervention: Philosophy, methodology,
Human Ecology Section was established to discuss and and practice. New York: Kluwer Academic/Plenum.

r
apply the ideas and methods of human ecology and allied Millennium Ecosystem Assessment. (2005). Ecosystems and human well-

D
disciplines. The Proceedings of the National Academy of being: Synthesis. Washington, DC: Island Press.
Ostrom, Elinor. (1990). Governing the commons: The evolution of
Science (PNAS) also include a sustainability science sec-

e
institutions for collective action. Cambridge, UK: Cambridge
tion committed to publishing research dealing with the

l
University Press.
interactions between natural and social systems and their Pimental, David; Westra, Laura; & Noss, Reed F. (Eds.). (2000).

p
impacts on sustainability. Leading academic institutions, Ecological integrity: Integrating environment, conservation, and health.
Washington, DC: Island Press.
including Stanford University in California, are also estab-

m
Power, Mary E., & Chapin, F. Stuart, III. (2009). Planetary steward-
lishing groups to investigate sustainability issues with a ship. Frontiers in Ecology and the Environment, 7(8), 399.

a
human-ecological perspective. With these and other arenas Rosa, Eugene, A.; Diekmann, Andreas; Dietz, Thomas; & Jaeger, Carlo

S
opening up, human ecology will be well placed to make its C. (2009). Human footprints on the global environment: Threats to sus-
tainability. Cambridge, MA: MIT Press.
contribution to sustainability challenges. Scheffer, Marten. (2009). Critical transitions in nature and society.
Princeton, NJ: Princeton University Press.
Robert DYBALL Schutkowski, Holger. (2006). Human ecology: Biocultural adaptations in
Australian National University human communities. Berlin: Springer.
Walker, Brian, & Salt, David. (2006). Resilience thinking: Sustaining eco-
See also Agricultural Intensification; Biogeography; Con- systems and people in a changing world. Washington, DC: Island Press.
Wilkinson, Richard, & Pickett, Kate. (2009). The spirit level: Why greater
servation Biology; Ecosystem Services; Indigenous and
equality makes societies stronger. New York: Bloomsbury Press.
Traditional Knowledge; Land-Use and Land Cover Young, Gerald L. (1978). Human ecology as an interdisciplinary domain:
Change—Management; Permaculture; Urban Agriculture An epistemological bibliography. Monticello, IL: Vance Bibliographies..
“ The Business of Sustainability [vol. 2]
would make an impressive stand-alone
business reference. Some of the concepts pages from Volume 1,
The Spirit of Sustainability
addressed, e.g., “triple bottom line,”
“peace through commerce,” and “base
of the pyramid,“ though not new, are
not widely known and deserve the extra
prominence that this book confers.
—Choice, November 2009 ” Volumes 1–10
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10-Volumes (complete set)
THE HUMAN SYSTEM
HOMO SAPIENS SAPIENS
Adaptation:

Respond
Control
Manipulate
 1. Biological Characteristics
a. Bipedal Locomotion
Balance
Sight
Prehensile forelimbs
Positive feedback mechanism
b. Manipulative Skill
 Power grip

Precision grip
c. Well-developed Vocal System
Speech vs. Call System
 Need for communication

Physical mechanisms
present
Specific Anatomical Attributes for Speech :

Well-developed brain
Homo symbolicus
Language
Acquisition Device
(LAD)
Pharynx
Tongue
Auditory apparatus
 Developed Human Brain
Cerebral Cortex

Speech Emotional
aspects
Logic
Integration of
Order speech
Spatial
 2. Social Characteristics
a. Dev’t of Technology
Freedom…
Tools to make other tools
Frequency & use
Tool dependence
b. Use of Language

Distinctly human
Symbolizing
First non-human to acquire a
human language 2007 (42 yrs) +
 Distinct Features of Speech:

✔Open
✔Arbitrary
✔Stimulus-free
✔Discrete
 Social Learning

People engage in group living because
it offers them opportunity for learning
and development.
 Socialization

Process where learning takes place is
called socialization which enables
individuals to learns the norms,
values, languages, and the like.
 Social Organization

The single most crucial factor
underlying social organization is
kinship.
Human Needs
1. Maslow’s Hierarchy of Needs
Basic Premises
individuals must satisfy The higher up the hierarchy, the
lower-level deficit needs before more difficult it is to satisfy the
progressing to meet higher-level needs associated with that
growth needs. stage, because of the
later clarified that satisfaction of interpersonal and environmental
a need is not an “all-or-none” barriers
phenomenon
Hierarchy of needs summary
Human beings are motivated by a hierarchy of needs.
Needs are organized in a hierarchy of prepotency in which
more basic needs must be more or less met (rather than all or
none) before higher needs.
The order of needs is not rigid but may be flexible based on
external circumstances or individual differences.
Most behavior is multi-motivated, that is, simultaneously
determined by more than one basic need.
 Self-actualization
"A musician must make music, an artist must paint, a
poet must write, if he is to be at peace with himself.
What a man can be, he must be.... It refers to man's
desire for fulfillment, namely to the tendency for him
to become actually what he is potentially: to become
everything that one is capable of becoming..."
Characteristics of Self- Actualizing People

Realistic & Reasonable
Self-acceptance
Spontaneity, Simplicity,
Naturalness
 Focus of Problem Centering
Detachment: The Need for
Privacy
Autonomy: Independent of
Culture & Environment
 Peak Experiences
Interpersonal Relations
Democratic Values & Attitudes
Philosophical & Has a Sense
of Humor
 Creativity
Imperfections

The SA person retains childlike
qualities yet is very wise.
Processes Necessary for Self-Actualization

▪ Self-exploration
▪ Action
The deeper the
self-exploration, the closer one
comes to self-actualization.
 Just answer T or F to each
question (if you cannot answer
100% True then answer F):
1. Other people are not better off
or more fortunate than me.
2. I accept myself as I am & am
happy with myself.
3. I enjoy socializing.
4. I deserve love & respect.
5. I feel valued & needed.
6. I don't need others to tell me I
have done a good job.
7. Being myself is important.
8. I make friends easily.
9. I can accept criticism without
feeling put down.
10. I admit my mistakes openly.
11. I never hide my true feelings.
12. I always speak up for myself &
put my views across.
13. I am a happy, carefree person.
14. I don't worry what others think
of my views.
15. I don't need others' approval
to feel good.
16. I don't feel guilty about doing
or saying what I want.

RESULTS of SELF-ESTEEM TEST (K.
Perera)

Count the total number of TRUE
answers YOU gave
Self-esteem is a key component in
happiness & self-actualization.

15-16: YOU HAVE A VERY HIGH
LEVEL OF SELF ESTEEM !
10-14: YOU HAVE A HIGH LEVEL
OF SELF-ESTEEM! ☺
BELOW 10: LOW SELF ESTEEM -
IT'S HOLDING YOU BACK
2. J.E. Montgomery’s Human Needs

✔Need to Relate to Others
✔Need for a Wholesome
Self-concept
True friends
are friends
forever !
✔ Need for Social &
Psychological Stimulation

✔ Creative &
Transcendental
Needs
 ✔ Need to Fulfill Values
An internalized
standard or guidepoint
 HUMAN POTENTIALS AND LIMITS
Potential – represents the capacity to
develop, to behave and to accomplish
which refers to undeveloped or latent
ability of each individual
 HUMAN POTENTIALS AND LIMITS
Limit – refers to what an individual or
group cannot develop, exhibit or
accomplish which is also determined by
his/her genetic endowment
HUMAN FAMILY
 The Concept of Family
Family – as the basic foundation of social
organization is another important
concern in the study of human system
Theories of Origin (Family)

Most anthropologists look at
the physiological and social
nature of humans and
compare it with other species
on the basis of survival
requirements.
Family as an
Ecosystem
Family with its
members interacting
with one another in a
particular physical or
social boundary, is an
ecosystem.
 a. Family
members
Elements of a
Family
Ecosystem
b. Environment
c. Family
organization
 Family boundaries or
Family household units are
Boundaries flexible. Boundaries are
and determined by the influx
Interfaces of information to the
family.
Adaptation and
Exchanges
Family is an open system
allowing exchanges of
material and energy with
other systems.
HUMAN
COMMUNITY
 HUMAN COMMUNITY

✔ A place to live in
✔ A spatial unit
✔ A way of life
✔ A social system
Community

It is composed of people living
together in a geographical
area with similar
characteristics, interests, goals/
need, share the same values &
depend on similar resources.
 Demography

▪ The study of populations
▪ Geographic boundary
▪ Population size, growth,
composition, density,
trends
 Community as a Spatial Unit
1) Physical Environment/ Habitat
▪ Shape- distribution or
construction of structures;
Topography
IRRI UPLB
 Hugo Yonzon, 1974

▪ Location
* “Mainit”: Bay
* Hot springs
* Friars – public
baths
* Los Baños (1589)
* 1615- separate
▪Size- number of people
* Affects the degree of Man -
Environment Interaction
* Natural Resources & Culture
2) 5 Ecological Processes
* Land use & space
competition
▪ Concentration
▪ Centralization -
centers of activity
 Vega Center

▪ Segregation- clusters of like units
▪ Invasion- gradual penetration of an
area
▪ Succession – complete change in
population type or use of land
Community as a Social
System

✔Social System
-highly organized set of socially
significant relationships between 2
or more persons/groups
✔The system of interaction of the various
units, which are highly related, that
compose the community.

Interaction Dynamism
TYPES OF
INTERACTION
 Types of Interaction
▪Cooperation- joint striving for
a goal
* Impersonal
* Mutual Aid Groups
▪Amalgamation - merging
▪Assimilation - blending or sharing of
ways of life
▪Competition- struggle for a goal
iOS or
Android?
▪Conflict- violent opposition
▪Accommodation- conscious efforts at
making things work
Boundaries

▪ Physical/Geographic
▪ Psychological-
acceptance
▪ Social ???
Community as an Organization/ Social
Group

▪Properties:
* Members
* Membership
* Roles & Norms
DY
▪Distinction
* Territorial boundary
* Roles & Norms
* Ability to provide for
needs of population
ENVIRONMENT
Biophysical (Natural) System
ENVIRONMENT
1. It is the total setting in which
a given object rests or a given
action takes place.
2. The physical, living & non-living
surroundings of society with which
it stands in a reciprocal
relationship.
3. The biotic and abiotic
surroundings of society & their
existing interactions.
-(Sajise, 1992)
4. Commonly perceived as the
immediate surroundings of an
individual.
The totality of the space,
elements & interactions

Human & society as important
elements
 Various
Conceptualizations
of the Environment
Form the Viewpoint of Human Physiology
1. Internal Environment
The environment of cells, organs, tissues and systems within the body.
The quality and stability of the internal environment is primarily
defined by the characteristics and conditions of the individual.

2. External Environment
The external environment such as the biophysical and social affects the
condition and behavior of the individual.
Form the Viewpoint of the Family
Management
1. Micro Environment
- The immediate physical and social surroundings of a
household which includes the following:
a) the natural and biological systems
b) the material technologies
c) organized social system of family members and others
who are responsible and interact to promote the goals of
that micro-system
Form the Viewpoint of the Family
Management
2. Macro Environment
- It is composed of the micro-environments which
contribute to resources inputs (energy, goods and services
and information) to the household and community
environments and receive outputs from these smaller
subsytems
From the Viewpoint of Resource
Management
1) Natural Environment
- Both the physical and biological materials and
energies

a) Physical or Inorganic Environment
- Consists largely of the cosmic forces, the sun’s heat
and energy and other cosmic forces which cause
climate changes.
b) Biological Environment
- All loving organisms,
microorganisms, parasites, insects
and plants and animals, which relate
symbiotically in nature, including
man.

2) Man-built Environment
- the transformation of the natural
physical and biological environments
which occur in the process of man
adapting nature to his needs.
a) Socio-physical Environment
- Include the physical or inorganic materials which are
transformed to meet human needs.

b) Socio-biological Environment
- Consist of the plants and animals bred or cultivated as
the basis for food, clothing and shelter.
3) Behavioral Environment
- concerns with human behavior processes as man
makes adjustments to his environment.

a) Socio-psychological environment
- it is consists of values, attitudes, expectations,
customs, traditions, etc. which make up the information
and decision-making patterns of individuals or groups.
b) Institutional environment
- The composite or derivatives that control
environments understood to be human institutions.
The institutional environments have the general
characteristics of the following:
Economic
Political
Educational
Ethical
aesthetic
The Interaction System
 Interrelatedness

❑ All living organisms respond to
individual factors in their environment
 Man has a great potential
to survive due to cultural
evolution.

Man: from a natural organism to
a technological one.
Flexibility of Humans
❑ Human Homeostasis
❑ Homeostatic limits
❑ Irreversible damage
Concepts in Human-Environment Interactions
A. Stress
- is an environmental
constraint that elicits a
human response
a. Biophysical
b. Social

* Natural & Human-induced
B. Human Adaptation
❖ Functional & Structural
Characteristics for COPING
❖ “Plasticity”
Human Adaptation as a Process

For survival &
perpetuation in his ever-
changing habitat
1. Biological Process

Long adaptive changes
mediated by genetic material

Adaptation is a
compromise !
2. Cultural Evolutionary Process

Culture as the instrument of adaptation
Somatic to extrasomatic energy use
 New energy
source/ tools

New organization of
social relations
Human Adaptation As an End Product

1. Developmental adjustments
- biological adjustments to
extreme & constant forms of
stress
- with irreversible anatomical or
physiological changes
2. Regulatory Adjustments

response w/c occurs very
rapidly as the stress is felt
3. Acclimatory Adjustments

biological responses which
requires changes in structure
General Adaptation
Syndrome (GAS)

Hans Selye (1976)
The body’s response to
different stressors show
some similarities
 st
1 stage: Alarm Reaction Stage
(Fight or Flight response)
nd
2 stage: Adaptation or
Resistance Stage
rd
3 Stage: Exhaustion Stage
Interaction Process
INTERACTION PROCESS:

The translation of environmental stimuli
into humanized meanings

▪ Ability to transform resources
▪ Social system
 Aspects Involved in Human -
Environment Interactions
1. Nature of the Interaction
Biophysical - material & energy
flow
Social - information flow &
language
2. Level of Awareness
Voluntary – deliberate efforts
Involuntary - unconscious & automatic
Roles of Interacting
Components

Proactive Role-
deliberate & exploitative
Reactive role- preservation
of life
Impact of Interaction on the Components
Favorable to one but unfavorable to
another (Predation, Parasitism,
Cannibalism)
 Favorable to both components
(Cooperation, Mutualism)
 Unfavorable to both components

Human Environment Interaction is not
a mutually exclusive event/ process.
 Levels of Human-
Environment Interaction
1. Individual-Environment Interaction

Individual-Individual
Prenatal Development
 Individual-Biophysical
2. Family-Environment Interaction

Family-Biophysical
 Family- Social Systems
3. Human Population/Community (HP/C)-
Environment Interaction

HP/C- HP/C Agri-Coop
 HP/C- Non-Human Living
Population
 HP/C- Biophysical Env’t
 HP/C- Natural
Environmental
Hazards
Cultural Adaptation

…the very mechanism by
w/c individuals, families
and communities are able
to interact with their env’t
to meet their needs/wants
toward Human Well-being.
The Seven Environmental Principles*

1. Everything is connected to everything else. (Ang lahat ng bagay ay magkakaugnay.)

The intricate relationships of various elements of the ecosystem bind the components together into
one functional unit. The trees in the forest are home to ferns, orchids, birds, insects and mammals.
When these plants and animals die, their products of decomposition contribute to soil fertility. Plants
provide oxygen to animals for aerobic respiration while animals furnish carbon dioxide to plants for
photosynthesis. The quality of the soil determines the type of vegetation that exists while vegetation
contributes to the minerals of the soil when they die. The living component of the ecosystem affects
and is affected by the abiotic components, such as air, temperature, land. Inter-specific relationships
create a dependency with each other so that they both have to co-exist to live. All these relationships
provide dependencies, check and balances that compose the details of our life-support systems.

Human interaction with nature oftentimes alters the ecosystems. The waste we improperly dispose
of brings about the deterioration of land and water quality. This may in turn reduce their capacity to
provide life for other organisms. Deforestation causes soil erosion and the earth deposited on the water
bodies covers the coral reefs resulting to fishery loss. Suspended particulates from vehicular and
stationary sources may cause lung problems among city residents. War causes destruction of wildlife
and habitats. There is a cause and effect chain, even when it is neither always visible nor observable.

Global economic systems affect the distribution of biological goods worldwide. Through the Galleon
trade, spices reached different parts of the world. Today, oranges and apples from China have become
easily accessible to the Filipino market. Developing countries argue that globalization promotes the
introduction of species detrimental to the recipient habitat and market.

2. All forms of life are important.(Ang lahat na may buhay ay mahalaga.)

All living organisms were created for a purpose in relation to humans, other species on earth and
global ecosystem in general. Thus, when a species becomes extinct, it is like removing a piece of a
jigsaw puzzle from the web of life. The variety of life forms, manifested by the different levels of
biological diversity – community, species and genes – contributes to the stability of the environment.
Food webs, food chains and ecological relationships link plants and animals together in the web of life.
Even bacteria, insects, snakes and rats have ecological functions even though humans perceive them as
parasites or pests.

The Philippines ranks high among the biodiversity hotspots – the richest but the most threatened of
terrestrial ecosystems in the world. The Philippines has rich flora and fauna: an estimated 13,500 plant
species, 80 amphibians, 240 reptiles, 556 birds, 174 mammals, 300 corals, 27 mangrove species. Of
these, approximately 75% are endemic. Some of the threatened species are the Philippine eagle
(Pythecophaga jefferyi), Philippine crocodile (Crocodylus mindorensis), and Tamaraw (Bubalus
mindorensis).

The composition of biological diversity naturally changes slowly but the rate of transition has
become faster due to factors such as habitat destruction. Deforestation may diminish forest species
such as birds that are vulnerable to modification of their home. Pollution of waters reduces the quantity
of fishes, shells, algae and other aquatic life. Over harvesting of natural products likewise contributes to
the unsustainable use of food and material resources.
 To maintain ecological balance, therefore, the conservation of genes, species and ecosystems
becomes essential to keep life together. Biodiversity conservation strategies commence with the
protection of both terrestrial and aquatic ecosystems. Land uses, such as protected areas, ensure that
the natural state of these habitats continue to exist in designated areas. Community-based approaches
in conservation maximize citizens’ participation in protected areas. Integrity of natural ecosystems can
likewise be guarded through the preservation of indigenous species.

Strategies outside of the protected areas can be adopted. Cities and human settlements can still
keep trees, patches of forests and garden as home for wildlife like birds, butterflies, and insects.
Agricultural ecosystems sustain the variety of plants and animals through inter-cropping, multi-cropping
and crop rotation. Plant and animal breeding can increase the population of commercially important
species without directly harvesting from the wild. The captive breeding of Pag-asa, the Philippine eagle,
provided a solution to the diminishing eagle population. Although it is still recommended that habitat
protection must be the first step to species protection.

3. Everything must go somewhere. (Ang lahat ng bagay ay may patutunguhan.)

By-products of consumption go back to the environment. Everything that we throw away – pieces
of paper, left-over food, peelings of fruits, plastic wrappers, used containers – have to go somewhere.
Even plants and animals have their own wastes – feces, urine, dead leaves and branches. It is the law of
nature that the by-products of metabolism return to the soil, acted upon first by worms, bacteria and
fungi, and then converted into minerals, to be again absorbed by plants and eaten by animals. In short,
they enter into a material cycle that is an integral part of the ecosystem. But what happens if what we
throw is an artificial product such as plastic? Then natural bacteria can not recognize them and may not
be capable of breaking them apart. These non-biodegradable products must enter another material
cycle – the one that goes to the factory to be manufactured into a new product. Thus the retrieval,
collection and recycling of these materials become necessary so that they do not pollute land and water
habitats.

In our present consumer-oriented, setting up an ecological solid waste management system
becomes necessary for maximizing the use of resources. Ecological solid waste management
recommends that solid wastes be reduced, segregated, re-used and recycled. Biodegradable materials
are either to be eaten again or composted. Non-biodegradable materials have to be segregated and
collected for recycling.

Industries have their own responsibility in reducing their effluents. End-of-the-pipeline
technologies are augmented by clean technologies in raw product extraction and manufacturing. The
“polluters pay” principle adopted by governments intensifies the campaign for clean land, water and air.
Waste exchange programs by industry turn wastes of one industry into raw products of another. In that
way, habitats for organisms are not destroyed or deteriorate.

4. Ours is a finite earth. (Ang kalikasan ay may hangganan.)

Everything that we need is provided by nature in abundance – food, water, energy, minerals and air.
However, some resources that we depend upon nowadays are extracted excessively but are slow to
replace. These non-renewable resources experience limits of supply. For instance, fossil fuels produced
over thousands of years may be exhausted in a hundred years. Some energy sources like water, and
wood may be replaced easier but have become inaccessible due to pollution and excessive extraction.
Diminishing forest cover have resulted from logging, ineffective reforestation and continued land
conversion. However, food scarcity and poverty may have resulted from failed distribution systems
rather than inability of the land and water bodies to yield food.

It can be argued that increasing population decreases the amount of resources available to each
person. Carrying capacity, or the ability of the ecosystem to support a number of people, may be
influenced by limit of resources due to an increasing population. Competition increases as the carrying
capacity is reached. Per capita consumption must also be taken into account because people in
Northern countries generally consume more food, energy and resources than people in the developing
Southern countries. Carrying capacity may be addressed two ways: increase resources and reduce
population growth. Agricultural productivity for instance may be increased with better availability of
water and farm inputs.

Pollution reduces the absorbing capacity of air and water. Pollution likewise reduces the
availability of land and water to produce food for human consumption. A river classified a Class IV
means that it becomes fit only for only for navigation and can no longer sustain life forms. Likewise, oil
spills from accidents or war destroy bays and rivers. Waterways that have become cesspool of domestic
wastes cannot contain fishes and shells or if they do might transmit toxins and harmful bacteria to
consumers.

Several solutions have been suggested to solve this problem: reduction of consumption,
increased use of renewable energy, emissions trading, and pollution control. The conservation ethic and
technological solutions have become viable strategies to address finiteness of resources. Biodiversity
conservation is anchored on the principle that lost species are irreplaceable. Thus, extinct species have
acquired a greater value – more effort has to be exerted to protect and save endangered species. The
conservation ethic supports the belief that we should tread lightly on the earth by using only what we
need. The philosophy of “sapat”, meaning “enough” suggests that we should buy and consume only
what we need and leave some for the less privileged and the next generation.

5. Nature knows best. (Ang kalikasan ang mas nakakaalam.)

Nature manifests certain processes that enable it to maintain balance and remain in a state of
equilibrium. The nutrient cycling of nitrogen, carbon, sulfur and phosphorous in the air, water and land
indicates that minerals are utilized within the confines of the earth. The flow of energy from the sun
enables light to be converted into sugar in plants through photosynthesis, and later for consumer
organisms to obtain energy from plant starch. Food chains and food webs allow transfer of energy from
producers and consumers and provide the means for all living organisms to acquire nutrition.
Population control also occurs naturally through predator – prey relationships.

The equilibrium in the ecosystem is maintained, thus if humans intervene, unforeseen negative
impacts known as ecological backlash, may arise. Floods are often times backlashes of excessive felling
of trees. The importation of golden kuhol, that became a pest, reminds us that biological organisms may
not acclimatize in a new environment or may cause harm to indigenous species.

The environmental ethics promote that we conform to ecological principles and stay close to natural
products and processes. We should patronize natural food and consumable materials. Organically
grown vegetables provide healthy food without the side effects that may arise from pesticides.
Ecological technology offers an option for us to choose, that which is closest to nature. The extent to
which Genetically Modified Organisms (GMOs) affect health remains debatable and the formidable task
of providing adequate safe food for a growing population continues to challenge agricultural scientists
and environmental managers worldwide.

6. Nature is beautiful and we are stewards of God’s creation. (Ang kalikasan ay maganda at tayo
ang tagapangasiwa ng lahat na nilikha ng Diyos.)

Creation presupposes the existence of a Creator. The beautiful nature around us, perfect by itself, has
deteriorated due to the negative impacts of human use. This principle suggests how a Human-Creator
relationship is translated in our attitude towards creation. Theologians explain that there are different
levels of this relationship. First is a relationship determined by dominion of humans over creation, that
humans can do as they wish because this was given by God. The book of Genesis says “have dominion
over the fish of the sea and the birds of the air…” The second level is one of stewardship, that of a
caretaker where humans are not owners but guardians of the integrity of nature. The third level
promotes a kinship relationship postulated by St. Francis de Assisi in the famous verse “Bother sun,
Sister moon”, where humans are no higher than the birds and fishes of the sea. Fourth is one of
sacrament, where nature becomes a testimony of God’s love. Fifth is a covenant relationship, where
protection of the earth is a life mission manifested in the things that we do and say.

Different religions from Islam to Buddhism to Judeo-Christian to indigenous people’s animism
express the belief of caring for the earth, including all creatures. Thus it is the goal of environmental
education and biodiversity conservation education to motivate target audiences towards developing an
eco-spirituality that moves them into a more meaningful relationship with nature and a greater
participation in the biophysical economic processes that make this world a better place to live in.

7. Everything changes. (Ang lahat ay nagbabago.)

Changes in the biophysical world occur naturally. As they say, there is nothing more permanent in
this world than change. Consider the following examples. Metamorphosis of caterpillars to butterflies
illustrates morphological changes that occur in living forms. The increase of vegetation on earth
augmented the amount of oxygen in the atmosphere through time. Seasons are cyclic changes that
contribute to the diversity of flowers, fruits, vegetables and other crops during the year. Random
changes manifested by natural catastrophe such as typhoons destroy forests, coral reefs and
mangroves. Volcanic eruptions annihilate surface flora and submerge rivers.

Human-induced alteration such as climate change may cause more massive repercussions. Land use
change – from forests to agricultural land to human settlements – change the composition of vegetation
and animals. Human-induced changes can be managed so that the negative impacts are minimized and
positive changes accentuated. Environmental impact assessment (EIA) provides a tool for the
projection, planning and management of change brought about by industrialization and human
settlement expansion. Effluents can be managed through policy and pollution control techniques by
both industry and government to achieve clean air and water.

Sustainable development presents a paradigm of change for the 21st Century. Sustainable
development promotes ecological integrity, equitable sharing of resources and people empowerment as
pillars of growth. Biodiversity conservation contributes to ecological integrity, through both in-situ and
ex-situ techniques. Biodiversity conservation becomes successful only if coupled with poverty
alleviation, improving equity of access to resources and instituting social change. Environmental
education facilitates social transformation by modifying attitudes and behavior of people towards an
ecological ethic.

*Adapted from Barry Commoner, as compiled by Miriam College.
Society for the Conserv ation of Philippine Wetlands. Inc.
Environment
…“immediate surroundings of an individual”
…”is a complex system that deals with a
network of living and non-living entities”

Includes:
Physical Components (air, water, land,
energy)
Biological Components (plants, animals)
Socio-Economic Components (people,
communities, institutions, values)
 The Seven Environmental Principles
(Barry Commoner)

I. Everything is connected to everything else.

Ecosystem
is the basic functional unit of nature
is the interaction of the community (living components) and
the non-living environment
The Seven Environmental Principles
(Barry Commoner)
The Seven Environmental Principles
(Barry Commoner)
 Philippine Ecosystem
The Seven Environmental Principles
(Barry Commoner)

Forest Ecosystems
Is a community of trees, shrubs, herbs,
microorganisms and animals, the trees being the
most obvious living structure
Marginal Lands/Uplands
Public lands that are hilly to mountainous and
greater than 18% slope, including the table land
and plateaus lying at elevations which are not
normally suited to wet rice unless some form of
terracing and ground water exists
Protected Areas
Areas of remarkable and outstanding features
considered as biologically important and are
habitats or rare and endangered species.
 Philippine Ecosystem
The Seven Environmental Principles
(Barry Commoner)

Freshwater and Wetlands
Areas of marsh, fen, peatland, or water, whether
natural or artificial, permanent or temporary,
with water that is static or flowing, fresh,
brackish, or salt, including areas of marine
water, the depth does not exceed six meters.
Lowland/Agricultural Ecosystems
Coastal and Marine Ecosystems
Home to 59% of the country’s total population
(70% of total municipalities and most of the
country’s major cities are located here)
Urban Ecosystems
 The Seven Environmental Principles
(Barry Commoner)

II. All forms of life are important
(thus, the need for biodiversity)
 All organisms have a role in the ecosystem (niche)
The Seven Environmental Principles
(Barry Commoner)
 Biological Diversity or Biodiversity
The Seven Environmental Principles
(Barry Commoner)

…”is the variety of all life forms on
Earth – plants, animals,
microorganisms…”

Ecosystems diversity - interdependence
within species
Species diversity – basic unit of
biological classification
Genetic Diversity – variation within
species

http://www.regentsprep.org/regents/biology/units/ecology/biodiversitycomparison. gif
 The Seven Environmental Principles
(Barry Commoner)

III. Everything must go somewhere
(thus, too much can cause pollution)
 Waste Management
 Environmental Management Systems
 The Seven Environmental Principles
(Barry Commoner)

IV. Ours is a finite earth
(thus, the need for conservation)
 Trends in Paradigm

Preservation Conservation Sustainable
(no touch) (Wise Use) Development
The Seven Environmental Principles
(Barry Commoner)
 Sustainable Development
The Seven Environmental Principles
(Barry Commoner)

…”development that meets the needs of the present
without compromising the ability of the future generations
to meet their own needs.”

Taken from the Brundtland Report “Our Common Future”, 1987.
 Natural Resource Management
The Seven Environmental Principles
(Barry Commoner)

Natural Resources can be classified into:
 renewable (forest)
 non-renewable (minerals)
 Natural Resource Management Approach
The Seven Environmental Principles
(Barry Commoner)

 Reforestation, community-based
management
 Soil and water conservation techniques, e.g.
agroforestry
 Biodiversity Conservation through PA
establishment
 Regulation of Wildlife Trade
 Ex-situ conservation techniques
 Integrated coastal resources management
 Environment-friendly aquaculture
 Solid Waste Management
 Community Organizing/involvement
 The Seven Environmental Principles
(Barry Commoner)

V. Nature knows best
(thus, the need for
ecological technology)
“Nature must be obeyed first
before it can be
commanded”
 Humans should first understand
nature and follow its laws
 Humans should not go against
natural processes if we want a
sustained yield of natural resources
 The Seven Environmental Principles
(Barry Commoner)

Natural Processes
Food Chain
Energy Flow
Diversity
Evolution
Ecological succession
Ecological control or
cybernetics
Biogeochemical cycles (e.g.
carbon-oxygen cycle,
nitrogen cycle, water cycle)
 The Seven Environmental Principles
(Barry Commoner)

Disruptions are in the form of:
 Illegal logging
 Indiscriminate kaingin-making
and forest fires
 Dynamite and cyanide fishing
 Habitat destruction resulting in
biodiversity loss
Can you think of other
disruptions?
 The Seven Environmental Principles
(Barry Commoner)

VI. Nature is beautiful and we are
stewards of God’s creation
 Divinity in all forms of life.
 Religion is one of the most influential aspects
that affect values and environment.
 The Seven Environmental Principles
(Barry Commoner)

VII. Everything changes.
Linear change – evolution of species
Cyclical Change – influenced by time such as seasons
Random Change – eruption of Mt Pinatubo
 SUMMARY
The Seven Environmental Principles
(Barry Commoner)

1. Everything is Connected to Everything Else
 Ecosystem
2. All forms of life are important
 Roles and niches, biodiversity
3. Everything Must Go Somewhere
 There is no ‘away’
4. Ours is a finite Earth
 No touch, wise use, sustainable development
5. Nature knows best
 Nature must be obeyed first before it can be commanded
6. Nature is Beautiful and We are Stewards of God’s Creation
 Religion is one of the most influential aspects that affect values and
environment
7. Everything Changes
 Linear, cyclical, random

22
 The Seven Environmental Principles
(Barry Commoner)

Workshop
 Connect ideas from the game with any of the
abovementioned principles
 Discuss relevance in everyday life.
Why Good People Do Bad
Environmental Things
Elizabeth R. DeSombre
 1

Understanding Environmental Behavior

Are you worried about the changing global climate? There’s good reason to
be: the atmospheric concentration of greenhouse gases has nearly doubled
since the beginning of the Industrial Revolution, and almost every recent
month has set new temperature records for the modern era. The predicted
effects of this increase in global average temperature—including sea-level
rise, shifting disease vectors, increased drought in some places and storms
and floods in others—are already happening.1
Maybe you’re concerned about toxic pollution, like heavy metals and other
hazardous materials from our increasing global use of electronics. At least
forty million tons of electronics waste is discarded every ye