Population Ecology ENVS 2300 PDF

Summary

This document provides an overview of population ecology, covering topics such as population characteristics, distribution, movement, and population dynamics. It explores concepts like exponential and logistic growth, and various factors influencing population regulation. The document also touches upon life history strategies and survivorship curves.

Full Transcript

Population Ecology – Objectives
To determine the characteristics of
populations
To compare models that describe exponential
and logistic growth
To determine the role of factors that regulate
populations
To explore different life history strategies
To interpret survivorship curves
 Population Ecology – Outline
Distribution and movement
spatial pattern
Exponential and logistic growth
regulation: dependent and independent factors
Population dynamics
Reproduction and survival
strategies
survivorship curves
Metapopulations
 Population - Definition
Group of individuals
that belong to the same species
occupy the same physical environment
at the same time
and can exchange genes
 Populations - Characteristics
Population-level properties
area of distribution
spatial pattern
density
age structure
sex ratio
survival / mortality rate
birth rate
growth rate
 Distribution
Affected by abiotic,
biotic factors
evolutionary history
dispersal
Geographic range vs.
distribution within

Molles and Laursen
 Patterns of population movement
Movement of organisms
Animals – mobile stages
Plants – seeds
Immigration and emigration are movements
in one direction
Expansion: movement from a source
Migration: regular and directional two-way
movement following a daily or seasonal
cycle
 Expansion
Also expansion of populations to
new regions, often introduced by
humans

Expansion of starlings
green = reproduction range
points = in winter

Riklefs and Miller
Expansion:
example

Molles and Laursen
Expansion following glacial retreat

Molles and Laursen
 Migration
From a region where resources are decreasing
towards a region where resources are (or will
be) abundant
Examples:
plankton – daily migration
crabs – migration with the tide
birds – seasonal migration
No effect on population dynamics
Effect on species composition and abundance of
organisms
Due to overabundance of seasonal resources
Migration:
example

Riklefs and Miller
Migration of sockeye salmon

Riklefs and Miller
 Migration of
whooping crane
 Spatial pattern
(dispersion)
Not all of the space is habitable
because of environmental
heterogeneity
> Non-uniform distribution of
individuals
Spatial pattern
Random
independent spatial positions
homogeneous environment
absence of attraction or repulsion
Uniform (regular)
regular spacing
intraspecific competition (e.g., territoriality)
competiton for resources
Aggregation
more frequent
reproduction, dispersal, social behaviour,
response to variation in the environment
facilitation in response to conditions.. depends on the scale

Townsend et al. Figure 5.12
 Population dynamics
Changes in population characteristics
size (# individuals), density (# per area)

Nt = Nt-1 + B - D + I – E
Nt = # individuals at time t
Nt-1 = # individuals at time t-1
B = # births
D = # deaths
I = # immigrants
E = # emigrants
 Exponential growth

N0 = 1
N1 = 2 N2 = 4
N3 = 8
Maximum possible rate of growth
Example of exponential growth

Copyright © 2010 Pearson Education Canada
Example of
exponential
growth

Molles and Laursen
Example of
exponential
growth

Molles and Laursen
 Population growth
We see exponential growth for
populations that are not dense
good conditions
initial phase of colonization
BUT a population cannot grow exponentially
indefinitely
Often populations collapse because of
famine, disease or emigration
OR regulated by density-dependent factors
 Population regulating factors
Density-independent
Affect the population regardless of its density
Destabilizing effect
Generally abiotic: climate (conditions)
Density-dependent
Act on the population in relation to its density
Often regulate population size
Generally biotic: intra- and interspecific
competition, predation
 Logistic growth

Biomass of a bacteria Gnu Plant Juncus gerardi
Begon et al.
Sigmoidal relation in the growth of a population
over time that reaches a threshold
corresponding to a carrying capacity (K)
Examples
of logistic
growth

Molles and Laursen
Explanation of the sigmoidal curve

Molles and Laursen
Exponential vs. logistic
population growth

28
Logistic growth: Tasmanian sheep

29
Growth of the whooping crane population
 Population dynamics
Change in population size with time
Continual growth towards K
Fluctuations: oscillations around K
Cycles: regular large fluctuations

Riklefs and Miller
Populations dynamics of reindeer
Copyright © 2010 Pearson Education Canada
Populations dynamics
 Different
population
dynamics

Townsend et al. Figure 9.4
Density of phytoplankton in Lake Erie

Riklefs and Miller
 Population cycles:
Predator-prey dynamics
Synchronized cycles (oscillations) of prey
and predator abundances
increase in prey > increase in predators
decrease in prey > decrease in predators
result of a delay
However, other factors may be involved
top-down (predation) vs. bottom-up (food
availability) or both
 Classic example:
snowshoe hare and lynx

Townsend et al.

Ricklefs and Miller
 Life history strategies
How an organism allocates energy among
different functions
Total energy is limited
Energy can be allocated to:
Survival (defence and functioning)
Growth
Reproduction
Therefore > trade-off among these vital
attributes
 r K
Survival and growth Survival and growth
Short life span Long life span
More energy for survival
Reproduction Reproduction
High reproduction rate Larger size of offspring
Lots of offspring More parental care or
High dispersal capacity nutrient reserves

Example: Example:
Weedy annual plants Trees
Opportunist species Competitor species
 r and K classification
In environments with abundant resources, ‘r’
populations allocate more energy for
reproduction.
In environments with limited resources
(intense competition), ‘K’ populations
allocate more energy for survival and
growth.
Continuum from r to K
Reproductive strategies

42
 Reproductive strategies
r species: high rate of population increase
K species: low rate of population increase
Survivorship curves
I: Mortality at the end
Humans, pandas, zoo animals
A lot of parental care
II: Constant mortality Begon et al.

Seed bank
Birds, rodents, woody plants
III: Extensive mortality followed by higher survival
Lots of offspring
Mortality low and constant after a critical size
More common, fish, invertebrates, annual plants
Survivorship curves
Type I

Molles and Laursen
Type II

Molles and Laursen
Type III

Molles and Laursen
 Effects of genetic variations
on population size
Can have greatest effects on small, isolated
populations
Loss of genetic diversity due to:
founder effect
demographic bottleneck
genetic drift
inbreeding
Metapopulations can aid in the survival
of small populations

49
 Metapopulations
Group of local populations (sub-populations)
linked by processes of emigration and
immigration
Model of the dynamics of metapopulations
(Levins 1969)
Dynamics of individuals within patches: birth,
mortality, movement
Dynamics of sub-populations in patches:
colonization, extinction, dispersal
Equilibrium at the level of the metapopulation
Metapopulation
example

Molles and Laursen
 Sources and sinks
Sources: reproductive success > mortality
Sinks: mortality > reproductive success
Emigration from sources > immigration to
sinks
Sources and sinks

Ricklefs and Miller
 POPULATIONS – Conclusions
Populations are characterized by their
distribution, movement, spatial and
survivorship patterns.
Population dynamics are variable but are
usually regulated by density-dependent
factors.
Species can be classified by their life history
strategies.