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Fall 2010 IB Workshop Series sponsored by IB academic advisors. Winning Resumes for IB Students Wednesday, Sept. 22 4:00-5:00pm 161 Noyes Lab
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Fall 2010 IB Workshop Seriessponsored by IB academic advisors Winning Resumes for IB Students Wednesday, Sept. 22 4:00-5:00pm 161 Noyes Lab Career Center staff will discuss the basics of writing a resume including format and objectives. Cover letters and special situations are also addressed.
ASSIGNMENT FOR THURSDAY 1) Complete Problem Set 3: 223-226 in lab manual 2) Go to: Course website for Sept. 24 Read article BEFORE class ‘Human Population Explosion’ 3) No LO or PPT for Thursday; only ICA.
This lecture Ch 10 + 12:Population Dynamics and Structure Read LO Major Concepts
Objectives • Temporal dynamics: fluctuations through time • Density-dependent vs. independent regulation • Types and causes of fluctuations • Models with time delays • Population abundance • How to estimate? • Age and sex structure • Spatial structures • Distribution (range) • Density • Dispersion
What determines the abundance and distribution of populations?Read LO I + II
What controls population size? density-dependent Chance?? K change in environment N density-independent time time time
Logistic equation assumes: • Instantaneous (d-d) feedback of K onto N • If time lags in response --> fluctuation of N around K • Longer lags---> more fluctuation; may crash. N K time
Density-dependent factors drive populations toward equilibrium(stable population size), • BUT • they also fluctuate around equilibrium due to: 1) changes in environmental conditions 2) chance 3) intrinsic dynamics of population responses
Fluctuation is the rule for natural populations. • Less fluctuation for large animals with • long life span because of: • greater homeostasis • many overlapping generations--> high intrinsic stability
Fluctuations greater if small/short lifespan • little homeostasis • populations turn over rapidly--> • low intrinsic stability
Population cycles synchronized among species in a region. Periodic cycles with peaks separated by same number of years.
Other species may vary in their response to changes in the environment --> asynchronized cycles.
Environmental fluctuations (extrinsic factors) (and organism responses) tend to be irregular, not periodic. But many populations change with periodic, non-random frequency. *** Is an extrinsic or intrinsic factor likely to be responsible? Explain.
Some populations exhibit regularfluctuations (cycles) in size.
What density-dependent factor causes grouse populations to cycle? Consider abiotic and biotic interactions…
What factor causes grouse populations to cycle? ICA 1 • Hypothesis: Density-dependent infections by a parasitic roundworm cause the cycles. • Prediction: Populations treated with anti-roundworm drugs will not crash following treatments, but control populations will. • Graph the prediction. Label axes.
Control:no drugs Control: No drugs
Results Experimental # Drug Drug Control # What is conclusion? Is hypothesis proven? Time
An intrinsicmechanism for population cycles? • ‘Momentum’ by high birth rate at low density --> overshoot K. • Low survival at high density--> overcompensate and decrease below K. • Population cycles result from time delays in the birth and death rates of populations in response to their own densities.
Discrete-time models with density-dependence: • Built-in time delay ---> can’t continually adjust • Patterns of oscillations depend on value of R • (per capita growth rate) >>2 chaos
Population dynamics reflect a complex interaction of biotic and abiotic influences, and are rarely stable.
Population: all individuals of a species in an area Subpopulations: in different habitat patches *** What are structures (traits) of populations? • Size (abundance) • Age structure • Sex ratio • Distribution (range) • Density (#/unit area) • Dispersion (spacing) • Genetic structure
Population size may be estimated by several methods, e.g. mark-recapture
Censusing a population • Number of individuals • Sex ratio • Age structure • complex if: • can’t age • size does not = age (plants) • Long-term vs. short-term
Size classes of individuals of same age.***What’s the ‘take-home message’ = main conclusion?
Temporal variation in recruitment of new individuals affects age structure ---> long-term implications on population growth.
Species distributions (ranges): are they really continuous? Read LO II
What must happen for species to extend range at periphery?What prevents it from doing so?
***What factors limit the (geographic) distribution (+ range) of organisms? • Phenology • Dispersal • Behavior (habitat selection) • Biotic factors (other species) • Abiotic factors (chemical / physical) • Human introductions • Chance • History
Geographic distributions are discontinuous. Within itsrange, only suitable habitatsare occupied.What factor determines this distribution?
ICA 2 • Transplant 2 species to • range of elevations --> • measure fitness components. • What is the main result : • for lowland species on L? • for highland species on R? • What is the main conclusion? LOW HIGH
Geographic range includes all areas occupied during entire life history; must include migration.
Geographic ranges with migration - know no political boundaries…adds complexity to protection.
Are ranges stable through time? Introduced starlings
Within its range, population density (#/area) varies with differences in habitat quality.
ICA 4 What accounts for this owl’s distribution? Owl location ‘Old growth’ forest
Density and reproduction success are dependent on amount of suitablehabitat for prey. Number per km2 Older forest (%)
Dispersion = spacing of individuals with respect to others in a population (Even) • Which is most common in plants? animals?
***What factors influence dispersion of individuals within populations? • habitat heterogeneity • dispersal limitation • reproductive mode • social interactions
Dispersal mode of plants affects their spatial dispersion.
ICA 5What type of dispersion is shown here? Hypothesize what causes the pattern. A B
