Theory of the dependence of population levels on environmental history for semelparous species with short reproductive seasons [Ecology, annual plants and many species of animals, particularly in the class Insecta]

• Published in: Proceedings of the National Academy of Sciences - PNAS Vol. 76; no. 10; pp. 5407 - 5410
• Main Authors: Coleman, Bernard D., Hsieh, Ying-Hen
• Format: Journal Article
• Language: English
• Published: United States National Academy of Sciences of the United States of America 01.10.1979; National Acad Sciences
• Subjects: Animals; Biological Sciences: Population Biology; Environment; Environmental history; Fecundity; Integers; Mathematical functions; Mathematics; Models, Biological; Mortality; Population Density; Population Dynamics; Population ecology; Population size; Reproduction; Species Specificity
• ISSN: 0027-8424; 1091-6490
• DOI: 10.1073/pnas.76.10.5407

A population that is strongly self-regulating through density-dependent effects is expected to be such that, if many generations have elapsed since its establishment, its present size should not be sensitive to its initial size but should instead be determined by the history of the variables that describe the influence of the environment on fecundity, mortality, and dispersal. Here we discuss the dependence of abundance on environmental history for a semelparous population in which reproduction is synchronous. It is assumed that at each instant t: (i) the rate of loss of members of age a by mortality and dispersal is given by a function $\rho $ of t, a, and the present number x = x(a,t) of such members; and (ii) the number x(0,t) of members born in the population is given by a function F of t and the number of x(a$_{f}$,t) at a specified age a$_{f}$ of fecundity. It is further assumed that the functions $\rho $ and F have the forms $\rho $(x,a,t) = $\pi _{1}$(a,t)x + $\pi _{2}$(a,t)x$^{2}$ and F(x(a$_{f}$,t),t) = $\nu _{t}$x(a$_{f}$,t). For such a population, a change in the environment is significant only if it results in a change in $\nu _{t}$, $\pi _{1}$(a,t), or $\pi _{2}$(a,t), and, hence, the history of the environment up to time t is described by giving $\nu _{\tau}$, $\pi _{1}$(a,$\tau $), and $\pi _{2}$(a,$\tau $) for each $\tau \leq $ t and all a in [0,a$_{f}$]. We show that the dependence of x on the history of the environment can be calculated explicitly and has certain properties of ``fading memory''; i.e., environmental events that occurred in the remote past have less effect upon the present abundance than comparable events in the recent past.