Fundamentals of Conservation Biology. Malcolm L. Hunter, Jr.
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Ecosystem | A | B | C |
---|---|---|---|
Black oak | 40 | 120 | 80 |
White pine | 30 | 60 | 60 |
Red maple | 20 | 20 | 60 |
Yellow birch | 10 | ||
Richness | 4 | 3 | 3 |
Evenness | 0.92 | 0.88 | 0.99 |
H | 0.56 | 0.39 | 0.47 |
H = −∑pi log pi, where pi is a measure of the importance of the ith species.
Evenness = H/Hmax where Hmax is the maximum possible value of H.
The ecological importance of species richness seems quite evident, especially if you consider the loss of richness through extinction. Similarly, most conservation biologists would be concerned about any process that reduced evenness, because this would mean uncommon species are becoming less common, while common species are becoming more common. To return to our jury metaphor, this would be analogous to losing a man from the jury that only had two men. Richness and evenness are often combined into a single index of diversity using mathematical formulae (Table 2.2) but, as we will see in the next sections, such indices are of limited utility.
The Mismeasure of Biodiversity
Often, being precise and quantitative will reveal solutions to a difficult problem, but using quantitative indices of diversity can be misleading when maintaining biodiversity is the goal. Consider the following three lists of species, each one representing (in very abbreviated form) a sample of the species found in three different types of ecosystems.
Forest | Marsh | Grassland |
Black oak | Reed‐grass | White prairie‐clover |
American toad | Painted turtle | Horned lark |
Eastern racer | Red‐winged blackbird | Black‐footed ferret |
Scarlet tanager | Muskrat | |
Raccoon |
If someone were asked which of these tracts is most important from the perspective of maintaining biodiversity, one measure of biodiversity – species richness – would suggest that the forest be chosen. However, if you knew that the black‐footed ferret is one of the rarest mammals in the world and that all the other species listed are very common, you might well select the grassland tract. Why?
The simple answer is that all species may count the same when tallying species richness, but conservationists almost always consider additional information such as the likelihood of a species becoming extinct, its role in an ecosystem, and more. Consequently, not all species are equal from a conservation perspective. We will return to this issue in other chapters, but we need to build a foundation here by considering how conservation decisions are shaped by patterns of diversity and risk of extinction at different spatial scales.
Biodiversity and Spatial Scales
Extinction usually refers to the disappearance of a species from the Earth, but the term is also routinely used, with modifiers, to describe the disappearance of a species from a smaller area. For example, when a species disappears from a small area, this is called a local extinction, even though the area may later be recolonized by immigrants, e.g. when beavers return to a valley from which they had disappeared. On a somewhat larger scale one can refer to regional extinction. For example, during the last century the bald eagle went extinct in many regions of the United States while remaining abundant in Alaska. Although conservation biologists are most concerned about global extinctions, smaller‐scale extinctions are also of some concern because they may foreshadow extinctions on a larger scale and because they may represent a loss of genetic diversity. Another key term is endemic, which refers to species found only in a defined geographic area; thus, koalas are endemic to Australia. If a species is found only in a very limited area (e.g. inhabiting only a single small island or lake), it is sometimes called a local endemic. For example, there is a snail known only from the base of a single waterfall in Chittenango, New York – the Chittenango ovate amber snail.
The risks of extinction at different spatial scales are a key consideration when deciding which endangered species are a higher priority. The larger the scale at which an extinction is likely to occur, the more important it is to try to prevent it. For example, the Iberian lynx, a species confined to southern Spain, is a higher priority for Spanish conservationists than the Eurasian lynx, which has a huge range that just reaches northern Spain (Fig. 2.2).
Figure 2.2 Conservationists do not consider all species to merit equal attention. For example, Spanish conservationists place a higher priority on protecting the Iberian lynx, a species now endemic to southern Spain that faces global extinction, than on the Eurasian lynx, a species threatened with regional extinction from the Pyrenees Mountains along the Spanish–French border but still relatively secure in other parts of Europe and Asia.
(Apple2499/Shutterstock)
The ecologist Robert Whittaker (1960) devised a simple system for classifying the scales at which species diversity occurs: alpha, beta, gamma (A, B, C in Greek). Alpha diversity is the diversity that exists within an ecosystem. In Fig. 2.3 two hypothetical lizard species, spotted lizards and long‐tailed lizards, illustrate alpha diversity by coexisting in the same forest, living at different heights within the forest. A third species, banded lizards, illustrates beta diversity