Название | Ecology |
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Автор произведения | Michael Begon |
Жанр | Биология |
Серия | |
Издательство | Биология |
Год выпуска | 0 |
isbn | 9781119279310 |
Figure 4.14 Reconstructed static life table for the modules (tillers) of a Carex bigelowii population. The densities per m2 of tillers are shown in rectangular boxes, and those of seeds in diamond‐shaped boxes. Rows represent tiller types, whilst columns depict size classes of tillers. Purple‐walled boxes represent dead tiller (or seed) compartments, and arrows denote pathways between size classes, death or reproduction.
Source: After Callaghan (1976).
Callaghan (1976) took a number of well‐separated young tillers and excavated their rhizome systems through progressively older generations of parent tillers. This was made possible by the persistence of dead tillers. He excavated 23 such systems containing a total of 360 tillers, and was able to construct a type of static life table (and fecundity schedule) based on the growth stages (Figure 4.14). There were, for example, 1.04 dead vegetative tillers (per m2) with 31–35 leaves. Thus, since there were also 0.26 tillers in the next (36–40 leaves) stage, it can be assumed that a total of 1.30 (i.e. 1.04 + 0.26) living vegetative tillers entered the 31–35 leaf stage. As there were 1.30 vegetative tillers and 1.56 flowering tillers in the 31–35 leaf stage, 2.86 tillers must have survived from the 26–30 stage, and so on. In this way, a life table – applicable not to individual genets but to tillers (i.e. modules) – was constructed.
There appeared to be no new establishment from seed in this particular population (no new genets); tiller numbers were being maintained by modular growth alone. However, a ‘modular growth schedule’ (laterals), analogous to a fecundity schedule, has been constructed.
Note finally that stages rather than age classes have been used here – something that is almost always necessary when dealing with modular iteroparous organisms, because variability stemming from modular growth accumulates year upon year, making age a particularly poor measure of an individual’s chances of death, reproduction or further modular growth.
4.7 Reproductive rates, generation lengths and rates of increase
4.7.1 Relationships between the variables
In the previous section we saw that the life tables and fecundity schedules drawn up for species with overlapping generations are at least superficially similar to those constructed for species with discrete generations. With discrete generations, we were able to compute the basic reproductive rate (R0) as a summary term describing the overall outcome of the patterns of survivorship and fecundity. Can a comparable summary term be computed when generations overlap?
Note immediately that previously, for species with discrete generations, R0 described two separate population parameters. It was the number of offspring produced on average by an individual over the course of its life; but it was also the multiplication factor that converted an original population size into a new population size, one generation hence. With overlapping generations, when a cohort life table is available, the basic reproductive rate can be calculated using the same formula:
and it still refers to the average number of offspring produced by an individual. But further manipulations of the data are necessary before we can talk about the rate at which a population increases or decreases in size, or, for that matter, about the length of a generation. The difficulties are much greater still when only a static life table (i.e. an age structure) is available (see later).
the fundamental net reproductive rate, R
We begin by deriving a general relationship that links population size, the rate of population increase, and time – but which is not limited to measuring time in terms of generations. Imagine a population that starts with 10 individuals, and which, after successive intervals of time, rises to 20, 40, 80, 160 individuals and so on. We refer to the initial population size as N0 (meaning the population size when no time has elapsed). The population size after one time interval is N1, after two time intervals it is N2, and in general after t time intervals it is Nt. In the present case, N0 = 10, N1 = 20, and we can say that:
(4.5)
where R, which is 2 in the present case, is known as the fundamental net reproductive rate or the fundamental net per capita rate of increase. Clearly, populations will increase when R > 1, and decrease when R < 1. (Unfortunately, the ecological literature is somewhat divided between those who use ‘R’ and those who use the symbol λ for the same parameter. Here we stick with R, but we sometimes use λ in later chapters to conform to standard usage within the topic concerned.)
R combines the birth of new individuals with the survival of existing individuals. Thus, when R = 2, each individual could give rise to two offspring but die itself, or give rise to only one offspring and remain alive: in either case, R (birth plus survival) would be 2. Note too that in the present case R remains the same over the successive intervals of time, i.e. N2 = 40 = N1 R, N3 = 80 = N2 R, and so on. Thus:
(4.6)
and in general terms:
and:
R, R0 and T
Equations 4.7 and 4.8 link together population size, rate of increase and time; and we can now link these in turn with R0, the basic reproductive rate, and with the generation length (defined as lasting T intervals of time). In Section 4.6.1, we saw that R0