Extinction dynamics of age-structured populations in a fluctuating environment.

Lande, Russell; Orzack, Steven Hecht

doi:10.1073/pnas.85.19.7418

Cited by 235 publications

(227 citation statements)

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“…Notably, the observed distribution of persistence times closely followed that predicted by stochastic population growth theory in which extinction results from fluctuations in population size caused by environmental and/or demographic stochasticity (Lande & Orzack 1988;Dennis et al 1991;Engen et al 2005; both the inverse Gaussian and the demographic distributions fitted the data well).…”

Section: Discussionmentioning

confidence: 51%

“…For small populations, such as the introductions considered here, fluctuations in population size due to demographic and environmental stochasticity are likely to be the major cause of extinction (Richter-Dyn & Goel 1972). For populations unaffected by density dependence and subject only to fluctuations caused by environmental stochasticity, stochastic population growth theory predicts that the distribution of persistence times will approach an inverse Gaussian distribution with parameters specifying the initial population size or viability, the long-term population growth rate and the variance due to environmental stochasticity (Lande & Orzack 1988;Dennis et al 1991). The inverse Gaussian distribution is highly skewed with a long right tail, so that the theory predicts that populations will either go extinct quickly or persist for a long time (Claessen et al 2005).…”

Section: (A) Data Collectionmentioning

confidence: 99%

“…The probability that a population persists for a given time is a widely used measure of population viability and the subject of much theoretical work aimed at predicting the fate of endangered species (Lande & Orzack 1988;Dennis et al 1991;Mangel & Tier 1993;Foley 1994). For small populations, such as the introductions considered here, fluctuations in population size due to demographic and environmental stochasticity are likely to be the major cause of extinction (Richter-Dyn & Goel 1972).…”

Section: (A) Data Collectionmentioning

confidence: 99%

See 2 more Smart Citations

Modelling population persistence on islands: mammal introductions in the New Zealand archipelago

Duncan

Forsyth

2006

Proc. R. Soc. B.

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Islands are likely to differ in their susceptibility to colonization or invasion due to variation in factors that affect population persistence, including island area, climatic severity and habitat modification. We tested the importance of these factors in explaining the persistence of 164 introductions of six mammal species to 85 islands in the New Zealand archipelago using survival analysis and model selection techniques. As predicted by the theory of stochastic population growth, extinction risk was the greatest in the period immediately following introduction, declining rapidly to low probability by ca 25 years. This suggests that initially small populations were at greatest risk of extinction and that populations which survived for 25 years were likely to persist subsequently for much longer. Islands in the New Zealand archipelago become colder and windier with increasing latitude, and the probability of mammal populations persisting on islands declined steeply with increasing latitude. Hence, our results suggest that climatic suitability was an important determinant of the outcome of these invasions. The form of the relationship between latitude and persistence probability differed among species, emphasizing that the outcome of colonization attempts is species-environment specific.

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Section: Discussionmentioning

confidence: 51%

Section: (A) Data Collectionmentioning

confidence: 99%

Section: (A) Data Collectionmentioning

confidence: 99%

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Modelling population persistence on islands: mammal introductions in the New Zealand archipelago

Duncan

Forsyth

2006

Proc. R. Soc. B.

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“…The total reproductive value equals the total population size N L if the population is exactly at its stable age distribution, and Engen et al (2007) showed that ln N L undergoes stationary fluctuations around ln V L with a return time to equilibrium of about one generation. That the process ln V L has approximately white noise explains the success of the diffusion approximation for ln V L (and ln N L ), identified simply as the Wiener process with infinitesimal mean and variancer L and s 2 L (Lande and Orzack 1988).…”

Section: Stochastic Demography and Reproductive Valuementioning

confidence: 99%

“…Because a diffusion process is subject to white noise with no temporal autocorrelation, the approximation is most accurate if the noise in the underlying biological process is approximately uncorrelated among years. Despite temporal autocorrelation in total population size produced by age-structure fluctuations, the stochastic demography of age-structured populations over timescales of a generation or more can nevertheless be accurately approximated by a diffusion process (Tuljapurkar 1982;Lande and Orzack 1988;Engen et al 2005aEngen et al , 2007. The success of the diffusion approximation for total population size occurs because the noise in the total reproductive value is nearly white, with no temporal autocorrelation to first order, and the log of total population size fluctuates around the log of reproductive value with a return time to equilibrium on the order of a few generations (Engen et al 2007).…”

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confidence: 99%

Reproductive Value and Fluctuating Selection in an Age-Structured Population

Engen¹,

Lande

Sæther

2009

Genetics

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Fluctuations in age structure caused by environmental stochasticity create autocorrelation and transient fluctuations in both population size and allele frequency, which complicate demographic and evolutionary analyses. Following a suggestion of Fisher, we show that weighting individuals of different age by their reproductive value serves as a filter, removing temporal autocorrelation in population demography and evolution due to stochastic age structure. Assuming weak selection, random mating, and a stationary distribution of environments with no autocorrelation, we derive a diffusion approximation for evolution of the reproductive value weighted allele frequency. The expected evolution obeys an adaptive topography defined by the long-run growth rate of the population. The expected fitness of a genotype is its Malthusian fitness in the average environment minus the covariance of its growth rate with that of the population. Simulations of the age-structured model verify the accuracy of the diffusion approximation. We develop statistical methods for measuring the expected selection on the reproductive value weighted allele frequency in a fluctuating age-structured population.

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Aggregation of Leslie matrix models with application to ten diverse animal species

Hinrichsen¹

2023

Population Ecology

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Some grouping is necessary when constructing a Leslie matrix model because it involves discretizing a continuous process of births and deaths. The level of grouping is determined by the number of age classes and frequency of sampling. It is largely unknown what is lost or gained by using fewer age classes, and I address this question using aggregation theory. I derive an aggregator for a Leslie matrix model using weighted least squares, determine what properties an aggregated matrix inherits from the original matrix, evaluate aggregation error, and measure the influence of aggregation on asymptotic and transient behaviors. To gauge transient dynamics, I employ reactivity of the standardized Leslie matrix. I apply the aggregator to 10 Leslie models developed for animal populations drawn from a diverse set of species. Several properties are inherited by the aggregated matrix: (a) it is a Leslie matrix; (b) it is irreducible whenever the original matrix is irreducible; (c) it is primitive whenever the original matrix is primitive; and (d) its stable population growth rate and stable age distribution are consistent with those of the original matrix if the least squares weights are equal to the original stable age distribution. In the application, depending on the population modeled, when the least squares weights do not follow the stable age distribution, the stable population growth rate of the aggregated matrix may or may not be approximately consistent with that of the original matrix. Transient behavior is lost with high aggregation.

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Extinction dynamics of age-structured populations in a fluctuating environment.

Cited by 235 publications

References 16 publications

Modelling population persistence on islands: mammal introductions in the New Zealand archipelago

Modelling population persistence on islands: mammal introductions in the New Zealand archipelago

Reproductive Value and Fluctuating Selection in an Age-Structured Population

Aggregation of Leslie matrix models with application to ten diverse animal species

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