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This makes me think that a variable (for a much grander model than what I'm futzing about with) would be some sort population plateau where the sheer number of an existing species would prevent continued evolution because any and all new mutations are eventually cycled back into the population at large; then the mutations are simply watered down and exist in isolated pockets, or just die out.
Let's look at an ideal stable ecosystem and an ideal ecosystem moving towards stability.
In an ideal stable ecosystem, all, or nearly all, of the available niches are filled by one species. Each species specializes in that niche and is so specialized that it can not survive outside of that niche. In this situation there will be no speciation (since we are dealing with an ideal situation). Natural selection will be pushing each species towards stability and away from change because every other possible "job" is already being done by another species and they are doing it better than your species could with just one generation of mutation. There are no ideal stable ecosystems, so this is a hypothetical situation. However, there are ecosystems that have been closestable for quite a long time and this is what we see.
In an ideal developing ecosystem, you start with two species. One is a prey species and the other is a predator species. This could be an herbivore/plant relationship or a carnivore/prey relationship. In this situation there are a lot of possibilities for change. There are empty niches all over the place. Plants will grow larger to prevent over grazing while other plants will grow smaller so that the fit into little cracks to avoid grazing. Prey species will either grow larger or get faster. I think you get the idea.
So in your model you also have to calculate the relative stability of the ecosystem. You could hypothetically calculate the maximum rate of speciation which would be tied in with the mutation rate and using the model of an initial two species ecosystem.
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Once the species reaches a certain level, it would become extremely resistant to additional speciation because the baseline genes (for lack of a better phrase) would keep the overall species characteristics near the mean.
The phrase that is often used is "fitness peak". This is an analogy that works quite well for this discussion.
Think of adaption as an uphill walk towards a peak which represents specialization. Each niche is then a peak with valleys between each of the niches. For a species to move into another niche it must go "downhill" (become less specialized), cross the valley, and then climb the next fitness peak. What happens in stable ecosystems is that the valleys become extremely deep. So deep that species are not able to make the traverse to the next peak. In a developing ecosystem the species are not very far up their fitness peaks. They are in the valleys and each path up each peak is a path of speciation.
You must also remember that the mutation rate is the same for every species regardless of the stability of the ecosystem. In a stable ecosystem, beneficial mutations are rare because the species are all well adapted. Therefore, neutral mutations will be selected for in a stable ecosystem. In a developing ecosystem there are many possible beneficial mutations most of which will be selected for.
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think this would be a sort of punctuated equilibrium argument, no?
Yeah, in a general sense. You will observe stasis in a stable ecosystem and punctuated evolution in developing ecosystems.
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