Population Ecology I. Attributes II.Distribution III. Population Growth – changes in size through time IV. Species Interactions V. Dynamics of Consumer-Resource Interactions VI. Competition
Population Ecology I. AttributesII.DistributionIII. Population Growth – changes in size through timeIV. Species InteractionsV. Dynamics of Consumer-Resource InteractionsVI. Competition
VI. COMPETITION
A. Empirical Tests of Competition
1. Gause
P. aurelia vs. P. caudatum
P. aurelia outcompetes P. caudatum.
VI. COMPETITION
A. Empirical Tests of Competition
1. Gause
P. aurelia vs. P. bursaria):
VI. COMPETITION
A. Empirical Tests of Competition
1. Gause
P. aurelia vs. P. bursaria: coexistence):
VI. COMPETITION
A. Empirical Tests of Competition
1. Gause
2. Park):
Tribolium castaneum
•Competition between two species of flour beetle: Tribolium castaneum and T. confusum.
TEMP HUMT. casteum won (%)
T. confusum won (%)
COOL dry 0.0 100.0
COOL moist 29.0 71.0
WARM dry 13.0 87.0
WARM moist 86.0 14.0
HOT dry 10.0 90.0
HOT moist 100.0 0.0
VI. COMPETITION
A. Empirical Tests of Competition
1. Gause
2. Park):
TEMP HUMT. casteum won (%)
T. confusum won (%)
COOL dry 0.0 100.0
COOL moist 29.0 71.0
WARM dry 13.0 87.0
WARM moist 86.0 14.0
HOT dry 10.0 90.0
HOT moist 100.0 0.0
Competitive outcomes are dependent on complex environmental conditions
Basically, T. confusum wins when it's dry, regardless of temp.
VI. COMPETITION
A. Empirical Tests of Competition
1. Gause
2. Park):
TEMP HUMT. casteum won (%)
T. confusum won (%)
COOL dry 0.0 100.0
COOL moist 29.0 71.0
WARM dry 13.0 87.0
WARM moist 86.0 14.0
HOT dry 10.0 90.0
HOT moist 100.0 0.0
Competitive outcomes are dependent on complex environmental conditions
But when it's moist, outcome depends on temperature
VI. COMPETITION
A. Empirical Tests of Competition
1. Gause
2. Park
3. Connell
):
Intertidal organisms show a zonation pattern... those that can tolerate more desiccation occur higher in the intertidal.
3. Connell - reciprocal transplant experiments
):
Fundamental Niches defined by physiological tolerances
incr
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esic
catio
n st
ress
3. Connell - reciprocal transplant experiments
):
Realized Niches defined by competition
Balanus competitively excludes Chthamalus from the "best" habitat, and limits it to more stressful habitat
VI. COMPETITION
B. Modeling Competition
1. Intraspecific competition
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
The effect of 10 individuals of species 2 on species 1, in terms of 1, requires a "conversion term" called a competition coefficient (α).
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
We can create an "isocline" that described the effect of species 2 on the abundance of species 1 across all abundances of species 2. For example, as we just showed, 10 individuals of species 2 reduces species 1 by 20 individuals, so species 1 will equilibrate at N1 = 60.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
and when N2 = 20 (exerting a competitive effect equal to 40 N1 individuals), then N1 will equilibrate at N1 = 40.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
And, when species 2 reaches an abundance of 40 (N2 = K1/α12) it drives species 1 from the environment (competitive exclusion). In this case, species 1 equilibrates at N1 = 0.
So, this line describes the density at which N1 will equilibrate given a particular number of N2 competitors in the environment. This is the isocline describing dN/dt = 0.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
Generalized isocline for species 1.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
And for two competing species, describing their effects on one another.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
Now, if we put these isocline together, we can describe the possible outcomes of pairwise competition.
If the isoclines align like this, then species 1 always wins.We hit species 2's isocline first, and then as abundances increase, species 2 must decline while species 1 can continue to increase. Eventually, species 2 will be driven to extinction and species 1 will increase to its carrying capacity.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
Now, if we put these isocline together, we can describe the possible outcomes of pairwise competition.
If the isoclines align like this, then species 2 always wins. We hit species 1's isocline first, and then as abundances increase, species 1 must decline while species 1 can continue to increase. Eventually, species 1 will be driven to extinction and species 2 will increase to its carrying capacity.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
Now, if we put these isocline together, we can describe the possible outcomes of pairwise competition.
The effects are more interesting if the isoclines cross. There is now a point of intersection, where BOTH populations have a non-zero equilibrium. This is competitive coexistence. And it is stable - a departure from this point drives the dynamics back to this point. Essentially, each species reaches it's own carrying capacity before it can reach a density at which it would exclude the other species.
VI. COMPETITION
B. Modeling Competition
2. Interspecific competition
Now, if we put these isocline together, we can describe the possible outcomes of pairwise competition.
Here the isocline cross, too. But each species reaches a density at which it would exclude the other species before it reaches its own carrying capacity. So, although an equilibrium is possible (intersection), it is unstable... any deviation will result in the eventual exclusion of one species or the other.