Ecology. Michael Begon

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Название Ecology
Автор произведения Michael Begon
Жанр Биология
Серия
Издательство Биология
Год выпуска 0
isbn 9781119279310



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      interference

      In other cases, competition takes the form of interference. Here individuals interact directly with each other, and one individual will actually prevent another from exploiting the resources within a portion of the habitat. For instance, this is seen amongst animals that defend territories (see Section 5.8.4) and amongst the sessile animals and plants that live on rocky shores. The presence of a barnacle on a rock prevents any other barnacle from occupying that same position, even though the supply of food at that position may exceed the requirements of several barnacles. In such cases, space can be seen as a resource in limited supply. Another type of interference competition occurs when, for instance, two red deer stags fight for access to a harem of hinds. Either stag, alone, could readily mate with all the hinds, but they cannot both do so since matings are limited to the ‘owner’ of the harem. Thus, with exploitation, the intensity of competition is closely linked to the level of resource present and the level required, but with interference, intensity may be high even when the level of the real resource is not limiting.

Schematic illustrations of the competition that may combine elements of both exploitation and interference. Intraspecific competition amongst cave beetles. (a) Exploitation. Beetle fecundity is significantly correlated (r equals 0.86) with cricket fecundity. The beetles themselves reduce the density of cricket eggs. (b) Interference. As beetle density in experimental arenas with 10 cricket eggs increased from one to two to four, individual beetles dug fewer and shallower holes in search of their food, and ultimately ate much less.

      Source: After Griffith & Poulson (1993).

      5.2.1 Density‐dependent mortality and fecundity

      under‐ and overcompensating density dependence

Graphs depict the density-dependent mortality. (a) Upper panel: the density of surviving adults of the barnacle, Semibalanus balanoides, in the UK as a function of the density of recruits two years earlier. Lower panel: the same data expressed as the relationship between the daily mortality rate and the density of recruits. (b) The density of surviving seedlings recruited to a population of the yellow star thistle, Centaurea solstitialis, in California as a function of the number of seeds present in the previous year.

      Source: (a) After Jenkins et al. (2008). (b) After Swope & Parker (2010).

      The lower panel plots the mortality rate against the initial number of recruits (mortality rate being calculated as –ln(S/R), where S and R are the number of survivors and recruits, respectively, divided by 730 (two years) to give a daily rate – similar to the intrinsic rate of natural increase, r, calculated in Section 4.7.1). We can see that at the very lowest abundances of recruits, the relationship was flat. That is, the mortality rate stayed the same and was thus density independent. There was no evidence of intraspecific competition when initial abundances were low. As those abundances increased, the slope of the relationship became positive – there was density dependence and thus evidence of competition – and that slope became steeper as the density dependence moved from under‐ to overcompensation.

      exactly compensating density dependence

      A similar relationship is shown in Figure 5.3b, but this time for a plant, the yellow star thistle, Centaurea solstitialis, in California, USA, relating the density of seedlings to the initial number of seeds in the soil. This time, though, at the highest seed densities, the number of surviving seedlings levelled off. The density dependence was exactly compensating: as initial density increased the mortality rate rose to counteract it.

      intraspecific competition and fecundity