Population Growth
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Transcript Population Growth
Population Growth
Population: a group the same species that live in the same
place at the same time
Resources: food, water, shelter, space and mates
In theory populations can grow to an infinite size, but they
are limited by resources
This causes individuals to compete for resources (remember
intraspecific and interspecific competition!).
Factors that Control Populations
There are 4 main factors
controlling population
sizes:
Natality - births increase the
population
Mortality - deaths decrease
the population
Immigration - movement of
individuals into an area
increases the population
Emigration - movement of
individuals out of an area
decreases the population
Carrying Capacity
Carrying capacity: maximum number of individuals of a
species that can be sustained indefinitely in a given space
No population can grow indefinitely! Resources = Limited!!
Limiting Factors of Populations
Factors (biotic or abiotic) which prevent population
numbers from growing too large and overrunning an
ecosystem.
Example:
Disease/ parasites
disasters
hunting & predation
competition for resources
(food, oxygen, nutrients)
Patterns of Population Growth
“J” population growth curve
Exponential growth = starts out slow and then
proceeds faster and faster
Occurs when a population has few resource limitations
Sudden collapse
('diebacks')
Patterns of Population Growth
“S” growth curve
(S for sigmoid)
Initially shows
exponential growth then
levels off at the carrying
capacity.
Occurs when a
population has limited
resources.
Results in stable
population
J Curve vs. S Curve
Population Dynamics
A look at the factors that tend to increase or decrease the size
of a population
The population size is determined by the interplay of biotic
potential and environmental resistance.
Biotic potential- growth rate with unlimited resources
Environmental resistance - all the factors acting jointly to
limit population growth
Biotic Potential vs. Environmental Resistance
Biotic potential
(Growth Factors)
Favorable light,
temperature
High reproductive rate
Adequate food supply
Ability to migrate
habitats
Ability to adapt to
environmental change
Environmental resistance
(Decrease Factors)
Too much or too little
light and temperature
Low reproductive rate
Inadequate food supply
Inability to migrate
habitats
Inability to adapt to
environmental change
Biotic Potential vs. Environmental
Resistance
Reproductive Strategies
r
Unstable environment,
K
Stable environment, density
Small size
Large size
Many offspring are produced
Few offspring produced
Early maturity
Late maturity (long parental
Short life span
care)
Long life span
Individuals reproduce more
than once
Type I or II survivorship curve
Each individual reproduces
once
Type III survivorship curve
Survivorship Curves
Type I - high survival rate of the young, live most of
their expected life span and die in old age. (ex.
Humans)
Type II - relatively constant death rate, could be due to
hunting or diseases. (ex. coral, squirrels, honey bees
and many reptiles)
Type III - have many young, most of which die very
early in their life. (ex. plants, oysters and sea urchins).
Survivorship Curves
Pop Quiz
Which type of survivorship curve does the cheetah
have?
What does parental care have to do with the shape of
these curves?
If you drew separate survivorship curves for female and
male cheetahs, what would they look like?
What do you think the survivorship curve would be for
a white-tailed deer population?
Density Dependent Factors
Density dependent factors
Depend on the size of the population
Effects of the factors increase as the population grows
Act as negative feedback
Tend to be biotic
Two categories:
Internal factors = Within a single species
limited resources
reduced fertility rates
External factors = between species
populations of predators or prey
diseases spread more easily in densely-populated areas
Snowshoe Hare and Canada Lynx
Density Independent Factors
Do NOT depend on the size of the population
Tend to be abiotic
Effect the population regardless of its size
Examples:
1. Weather
2. Earthquakes
3. Floods
4. Fires
R-strategists are most
affected by these factors
Ecological Succession: Change over
Time
Two Types of Succession
Primary succession - An ecosystem starts from bare
rock
Secondary succession – Ecosystem is built from a
previous ecosystem
Starts with soil
Important
Terms
Sere: A set of stages of changes in
an ecosystem.
A snapshot of ecosystem
Pioneer organisms: First species
that begin to populate a sere,
typically r-strategists.
Ex. Weeds, lichens
Climax community: Populations
of organisms living together in a
sere where all species are in
balance.
Ex. A mature forest, many Kstrategists
Pioneer Species
Primary Succession
No soil in a terrestrial
system
No bottom sediment in
an aquatic system
Takes hundreds to
thousands of years
Need to build up
soils/sediments to
provide necessary
nutrients
Primary succession will occur
after a volcanic eruption
Primary succession occurs after
a glacier retreats
Image source: http://www.callipygia600.com/
Primary succession occurs after
a glacier retreats
Primary succession occurs after
a glacier retreats
Glacier Bay, Alaska
Primary Ecological Succession
Lichens and
Exposed mosses
rocks
Small herbs
and shrubs
Heath mat
Jack pine,
black spruce,
and aspen
Balsam fir,
paper birch,
and white
spruce forest
community
Secondary Succession
Begins with soil from previous
ecosystem
Ecosystem has been
Disturbed, Removed, or
Destroyed
Abandoned farms
Burned forests
Deforestation
A huge storm
Secondary Succession
Annual
weeds
Perennial
weeds and
grasses
Shrubs and
small pine
seedlings
Young pine forest
with developing
understory of oak
and hickory trees
Mature oak and hickory
forest
Secondary Ecological Succession in Yellowstone Following
the 1998 Fire
Conditions during succession
Early Stages Gross
Productivity is Low
Not many producers
Later Stages Gross
Productivity is High
Climax Community