species abundance

biology
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Also known as: abundance
Also called:
abundance

species abundance, typically, the sum total of individuals from a given species within a given area. A species is considered abundant when it has a high population relative to the size of the area it inhabits. It can also include other measures of performance for plants, animals, or other forms of life in a given area, including number of breeding pairs, population density, and even biomass. In ecology, species abundance can serve as a tool to measure biological diversity and inform conservation efforts.

A distinction exists between absolute and relative species abundance. The former counts only the raw number of individuals of a species in a given area; the latter considers the proportion of individuals of one species within the wider biological community and measures how evenly the community’s total population numbers are distributed across species.

Patterns of species abundance

Researchers assessing abundance have observed several patterns that hold true across species, and these patterns can reveal the dynamics between different species and their environment. For instance, if two species are both abundant when separate but only one remains in large numbers in regions where both occur, it is likely that these species compete with one another (see also competition). In another example, if a species is abundant in one part of a habitat but absent in another part marked by an ecological disturbance, it is likely that a wildfire, flood, damaging wind event, or other disturbance limited the species’ abundance in the latter part.

Only a few species tend to occur in high numbers in most biological communities, and thus members of these species together make up the bulk of the community’s total population of individuals. This phenomenon may result from either niche differences (such as each species preferring a different part of the shared habitat or a different suite of food sources) or variations in neutral dynamics (which consider how randomness affects factors such as rates of birth, death, immigration, extinction, and speciation to change how abundant a species is at different times) in species whose ranges overlap with one another.

One central pattern of species abundance is called the distribution-abundance relationship. On a broad scale, species that are distributed over wider areas tend to have a greater population density than species that occupy smaller, limited areas. The main idea behind this relationship is intuitive: the total number of individuals in a habitat increases as the size of the habitat increases, since, all things being equal, a larger living space can support more individuals.

Conservation of biodiversity

In conservation, species abundance is one of several measurements used to assess biodiversity. A related but separate term, species richness, considers the number of unique species in a certain region rather than the population count of a single species. Both measures, however, do not necessarily correspond. In areas without a wide range of habitats, species richness may be very poor because of low habitat diversity, whereas species abundance might be high for the few species that are most successful there. A third term, species diversity, combines species abundance and species richness to gauge the number of unique species in a region along with each species’ population size.

Measuring species abundance can also inform conservation efforts with respect to rare and endangered species. To compile its Red List of Threatened Species, the International Union for Conservation of Nature and Natural Resources uses species abundance as one of its primary tools to assess the extinction risk of threatened plants, animals, and fungi. Species assessments often rely on examining trends that emerge from a series of population surveys (either through direct counts or through statistical tools that estimate population size). Such time series data help to illuminate patterns of population increase or decrease, which can then be placed in context with changes to a species’ habitat, geographic range, and demographic factors (such as birth rates, death rates, the ratios of breeding individuals to nonbreeding individuals, and the ratios of breeding males to breeding females) to determine the risk of that species becoming extinct.

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Anna Dubey