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Transcript
Living In EcosystemsPopulation Dynamics
Chapter 30
Copyright © McGraw-Hill Companies
Permission required for reproduction or display
Population Growth

Populations are composed of groups of
individuals of the same species living
together.

Critical Properties that affect
the dynamics populations
Population Size
 Population Density
 Population Dispersion
 Capacity for Growth

Population Growth


A population’s actual rate of
increase is the difference between
birth rate and death rate corrected
for migration.
Innate capacity for growth of any
population is exponential.

Even when rate of increase remains
constant, the actual increase in the
number of individuals accelerates
rapidly as the size of the population
grows.
Population Growth

Exponential Growth Model

Assumes population growing without
limits at its maximal rate.
(r = biotic potential)
dN/dt=riN
N = Number of individuals in population
 dN/dt = Rate of change in population size
over time
 ri = Intrinsic rate of increase

Population Growth

Carrying Capacity (K)


Number of individuals an area can
indefinitely support.
Logistic Growth Model

As population approaches its carrying
capacity, its growth rate slows as
resources become scarce.
dN/dt = rN (K-N/K)

Sigmoid Growth Curve
Take out a blank sheet of paper
On the paper write :
1.
your name (first and last)
2.
The date today (6/4)
3.
The letter of the correct answer to the following question
The population graph of brown sparrows exhibits which
type of population model?
A.) Exponential growth model.
B.) Balancing growth model.
C.) Logistic growth model.
D.) Predator – Prey growth model.
Two Models of Population Growth
Influence of Population Density

Density-Dependent Effects


Effects are independent of population
size and act to regulate growth
(weather).
Density-Dependent Effects

Effects are dependent on size of
population and act to regulate growth
(resource competition).

Have increasing effect as population size
increases.
The Niche and Competition

Niche - Biological role in community.



Fundamental - Theoretical role
Realized - Actual role
Competition - Two or more organisms
attempt to use same resource.




Interference - Fighting
Exploitative - Consuming shared resources
Interspecific - Different species
Intraspecific - Same species
Barnacle Competition
Competitive Exclusion

Gause - No two species can coexist
in the same niche indefinitely.

When two species coexist on longterm basis, their niches differ in one
or more features.

Otherwise,
one is eventually
driven to
extinction.
Resource Partitioning

Sympatric Species
- Occupy same
geographical area
but avoid
competition by
utilizing different
portions of the
habitat.
Resource Partitioning

Allopatric
Species - Do
not occupy
same
geographical
area, thus are
not usually in
competition.
Character
Displacement - Differences arise
between species due to natural selection.
Symbiosis

Symbiotic Relationship - Two or
more species of organisms live
together, and at least one gains
benefit.



Commensalism - One species benefits
while other neither benefits or is
harmed.
Mutualism - Both species benefit.
Parasitism - One species benefits while
the other is harmed.
Predator – Prey :Plant Defenses

Predator-Prey Interactions

Morphological Defenses


Chemical Defenses


Thorns, spines, plant hairs
Secondary chemical compounds
Evolution of herbivores avoiding
plant defense allows access to a
new resource without competition
from other herbivores.
Predator- Prey ; Animal Defenses

Feeding on plants rich in secondary
compounds may have added
benefit.


Defensive Coloration



Blue Jays and Monarch Butterflies
Aposomatic Coloration - Advertise
poisonous nature with bright coloration.
Cryptic Coloration - Camouflage
Chemical Defenses
Predator-Prey Cycles

Predation is consumption of one
organism by another.

Under simple laboratory conditions,
predators often exterminate their prey,
and then become extinct themselves
when they run out of food.

If refuges are provided for the prey, a few
individuals usually exist, and then
repopulate after the predators die out.
Predator-Prey Cycles

Snowshoe Hares (Lepus americanus).


Food - Willows
Predators - Canada Lynx (Lynx canadensis)
Predator- Prey cycle
Inter-relationships of species

What happens if the sparrow population
increases its reproduction rate to 8 eggs
per clutch?
Biodiversity
 Measure
of number of different
types of species in an area.

Crucial to ecosystem preservation.
 Biodiversity

Promotion
Ecosystem Size
 Larger
ecosystems, usually have
higher levels of biodiversity

Latitude
 Length
of growing season
 Climatic stability
Latitudinal Cline in Species
Richness