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Unit 3 - Population
3.1 Generalist & Specialist Species
some species (generalist feeders) adapt to environmental changes better than other species (specialist feeders)
generalist species: thrive in dynamic environments; can adapt well (broad niche)
can live in a variety of environments
broad range of ecological tolerance (no specific diet or habitat)
usually known for being invasive species
ex. raccoons, mule deers, rats, bald eagles
specialist species: thrive in stable environments; easily struggle or succumb to changes in habitat (narrow niche)
only live in specific conditions
narrow range of ecological tolerance (limited diet, conditions, and habitat)
ex. giant pandas, mountains gorillas, osprey
3.2 K-Selected & r-Selected Species
K-selected species: large, quality > quantity in offspring, long life spans, late maturation can reproduce multiple times, specialists, large body types, strong competition in their particular environments
high levels of competition for resources in the habitat
more prone to the colonization of invasive species
can maintain the population at carrying capacity (adjusting population to utilize resources efficiently)
ex. giant pandas, elephants
r-selected species: small, quantity > quality in offspring, early maturation, reproduce only once, generalists
low competition for resources in the habitat
prone to overpopulation by exceeding the carrying capacity
can experience population dieback due to overpopulation
ex. mosquitos, invasive species
biotic potential: max ideal reproductive rate of a population (measurement of growth capacity in populations)
ex. 1-2 cubs for giant pandas
many species have characteristics of both K-selected and r-selected species
ex. osprey, frogs, sea turtles
3.3 Survivorship Curves
survivorship curve: displays the relative survival rates of a group of same-age individuals in a population
x-axis: max lifespan of organisms from birth to death
y-axis: percent of surviving organisms in a population (logarithmically)
Types of Survivorship Curves
Type I: late loss
a large number of the population survives throughout their lifespan, reaching old age
dies at the end of their lifespan
adequate care → increasing chances of survival to maturation
represents many K-selected species
ex. mountain gorillas
Type II: constant loss
death rate constant from birth to death
organisms die throughout their lifespan
ex. birds, squirrels
Type III: early loss
surviving rate drops immediately after birth; few organisms survive to adulthood
little to no care → high infant mortality
represents many r-selected species
ex. monarch butterflies
3.4 Carrying Capacity
>= carrying capacity → resource depletion → famine, disease, and conflict
carrying capacity: max number of organisms the environment can support without resource degradation
represented as a horizontal dotted line at the top of the graph labeled K
population dieback: decrease in population as a result of resource degradation caused by overpopulation in species
exceeding carrying capacity → population dieback → within carrying capacity
ex. reindeer of st. matthew island
3.5 Population Growth and Resource Availability
environmental resistance: factors that limit population growth
emerges after the population goes over carrying capacity
exponential growth = unlimited resources
occurs in all populations below carrying capacity (competition does not greatly affect population growth)
logistic growth = limited resources
occurs in populations at or above carrying capacity when competition is a dependent variable
fecundity: ability to produce offspring
including factors such as maturation age, reproductive rate, biotic potential, and reproductive strategy
Types of Environmental Resistance Factors
density-dependent resistance factors: biotic, affects organisms when population density is high
ex. competition, predation, parasitism
density-independent resistance factors: abiotic, affects all populations regardless of size or density
ex. natural disasters or droughts
3.6 Age Structure Diagrams
another name for population pyramid
shows the distribution of ages in a population divided by males and females
shapes represent trends within the population
x-axis: # of individuals (left side male right side female)
y-axis: center of the diagram showing age groups
reproductive: 0-14 years
reproductive: 15-45 years
post-reproductive: 46-100+ years
higher proportion of young people = rapid population growth (bottom heavy)
wide base, pyramid shape
indicates developing nation
ex. india, brazil, nigeria, mexico
higher proportion of middle-aged people: stable population growth (middle heavy)
rectangular shape
similar percentages throughout all age groups
indicates more developed nations
ex. united states, sweden, canada, austrailia
higher proportion of elder people: declining population growth (top heavy)
inverted pyramid shape
many people in the post-reproductive stage
more economic and social development, higher education common
long-term impact on social services
ex. japan, germany, italy, russia
3.7 Total Fertility Rate
TFR: avg # of children a woman has during her childbearing years (15-49)
been lowering in recent years depending on the country
ex. world avg = 2.5
developing countries: TFR > 2.1
rapid population growth
ex. niger, congo, uganda
developed countries: TFR <= 2.1
stable/declining population growth
ex. united states, japan, united kingdom
Societal Factors
age of first pregnancy
educational opportunities for women
family planning resources
governmental regulations
access to healthcare resources
3.8 Human Population Dynamics
thomas malthus → all populations have a carrying capacity
humans are limited by density-independent & density-dependent factors
density-independent factors: affects population regardless of size or density
ex. storms, fire, heat waves, droughts
density-dependent factors: affects population based on size or density
arises during overshoot and dieback → decreasing overpopulation
ex. disease transmission, territory size, food availability, access to clean air and water
doubling time: the amount of time a population takes to double at a constant growth rate
calculated using rule of 70
rule of 70: 70/r = doubling time
r = growth rate of population (%)
Environmental Problems
density-independent factors
hurricanes → drop in population due to property damage, economic loss, and better opportunities elsewhere
more years a woman is in school = lower TFR
Societal Factors
birth rates:
high rate = rapid population growth
low rate = slow population growth
death rates:
high rate = slow population growth
low rate = rapid population growth
education of women:
high rate = slow population growth
low rate = rapid population growth
infant mortality:
high rate = slow population growth
low rate = rapid population growth
age of marriage:
early - rapid population growth
late - slow population growth
nutrition:
better = rapid population growth
worse = slow population growth
3.9 Demographic Transition
demographic transition: model that shows trends in CBR, CDR, and total population
derived from historical data
moving towards industrialization from agricultural-based economies
development shown in 4 stages
Stage 1: high infant mortality, child labor → low growth (preindustrial)
Stage 2: improved resources → very high growth (transitional)
the gap between birth and death rate widens
less developed countries (LDC)
Stage 3: high education amongst women, low infant mortality → slower growth (industrial)
less developed countries (LDC)
birth and death rate are almost equal
Stage 4: stage 3 + aging population + tax burdens for senior citizen care → zero or negative growth (post-industrial)
more developed countries (MDC)