Cycles of voles, predators, and alternative prey in boreal Sweden

Bank voles, grey-sided voles, and field voles had synchronous 3-4 year density cycles with variable amplitudes which averaged about 200-fold in each species. Cycles of vole predators (red fox and Tengmalm's owl), and their (foxes') alternative prey (mountain hare and forest grouse) lagged...

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Bibliographic Details
Main Author: Hörnfeldt, Birger
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: Umeå universitet, Ekologi och geovetenskap 1991
Subjects:
3-4 year cycles
Clethrionomys glareolus
Clethrionomys rufocanus
Microtus agrestis
snap-trapping
rate of change
population regulation
delayed density-dependence
time-lag mechanism
seasonality
predation
food
predator avoidance
foraging behaviour
Aegolius funereus
nest boxes
numerical response
nomadism
Vulpes vulpes
Sarcoptes scabiei vulpes
Lepus timidus
Francisella tularensis
Tetraonidae
hunting statistics
Ecology
Ekologi
Zoology
Zoologi
mountain hare
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-100711
Description
Summary:Bank voles, grey-sided voles, and field voles had synchronous 3-4 year density cycles with variable amplitudes which averaged about 200-fold in each species. Cycles of vole predators (red fox and Tengmalm's owl), and their (foxes') alternative prey (mountain hare and forest grouse) lagged behind the vole cycles. The nomadic Tengmalm's owl responded with a very rapid and strong numerical increase to the initial cyclic summer increase of voles (the owl’s staple food). Owl breeding densities in the springs were highly correlated with vole supply in the previous autumns. This suggested that the number of breeding owls was largely determined in the autumn at the time of the owl's nomadic migrations, and that immigration was crucial for the rapid rise in owl numbers. The owl's numerical response was reinforced by the laying of earlier and larger clutches when food was plentiful. In addition, the owl has an early maturation at one year of age. The transition between subsequent vole cycles was characterized by a distinct shift in rate of change in numbers from low to high or markedly higher values in both summer and winter. Regulation increased progressively throughout the cycle since the rate of change decreased continuously in the summers. Moreover, there was a similar decrease of the rate of change in winter. Rate of change was delayed density-dependent. The delayed density-dependence had an 8 month time-lag in the summers and a 4 month time-lag in the winters relative to the density in previous autumns and springs, respectively. These findings suggest that vole cycles are likely to be generated by a time-lag mechanism. On theoretical grounds, it has been found that a delayed density- dependence of population growth rate with a 9 month time-lag caused stable limit cycles with a period between 3 and 4 years. Some mechanisms for the delayed density-dependence are suggested and discussed. The mechanisms are assumed to be related to remaining effects of vole populations past interactions with predators, food supplies, ...

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