Density-dependent dispersal in integrodifference equations
From MaRDI portal
Publication:938149
DOI10.1007/s00285-007-0127-1zbMath1143.92038OpenAlexW2101242387WikidataQ51906125 ScholiaQ51906125MaRDI QIDQ938149
Publication date: 18 August 2008
Published in: Journal of Mathematical Biology (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s00285-007-0127-1
Lua error in Module:PublicationMSCList at line 37: attempt to index local 'msc_result' (a nil value).
Related Items (22)
Monotone traveling waves in a general discrete model for populations ⋮ Formulating spread of species with habitat dependent growth and dispersal in heterogeneous landscapes ⋮ Mate finding, sexual spore production, and the spread of fungal plant parasites ⋮ Analysis of spreading speeds for monotone semiflows with an application to CNNs ⋮ NonMonotonicity of Traveling Wave Profiles for a Unimodal Recursive System ⋮ Neutral genetic patterns for expanding populations with nonoverlapping generations ⋮ Coexistence and spread of competitors in heterogeneous landscapes ⋮ Seed predation-induced Allee effects, seed Dispersal and masting jointly drive the diversity of seed sources during population expansion ⋮ Analysis of integrodifference equations with a separable dispersal kernel ⋮ Propagation dynamics for a spatially periodic integrodifference competition model ⋮ Birth-jump processes and application to forest fire spotting ⋮ The critical domain size of stochastic population models ⋮ Persistence and spreading speeds of integro-difference equations with an expanding or contracting habitat ⋮ Impact of directed movement on invasive spread in periodic patchy environments ⋮ Asymptotic stability of monostable wavefronts in discrete-time integral recursions ⋮ Success, failure, and spreading speeds for invasions on spatial gradients ⋮ The effects of density-dependent dispersal on the spatiotemporal dynamics of cyclic populations ⋮ Should I stay or should I go: partially sedentary populations can outperform fully dispersing populations in response to climate-induced range shifts ⋮ Life on the Move: Modeling the Effects of Climate-Driven Range Shifts with Integrodifference Equations ⋮ On a chemotaxis model with degenerate diffusion: initial shrinking, eventual smoothness and expanding ⋮ Principal Eigenvalues of Generalized Convolution Operators on the Circle and Spreading Speeds of Noncompact Evolution Systems in Periodic Media ⋮ Approximating the critical domain size of integrodifference equations
Cites Work
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Effects of heterogeneity on spread and persistence in rivers
- Dispersion population models discrete in time and continuous in space
- The velocity of spatial population expansion
- Modeling biological invasions into periodically fragmented environments
- Biological growth and spread modeled by systems of recursions. I: Mathematical theory
- Biological growth and spread modeled by systems of recursions. II: Biological theory
- Existence and stability of travelling wave solutions of a nonlinear integral operator
- Traveling periodic waves in heterogeneous environments
- Discrete-time growth-dispersal models
- The evolution of slow dispersal rates: a reaction diffusion model
- Discrete-time travelling waves: Ecological examples
- Integrodifference models for persistence in fragmented habitats
- Nonsharp travelling wave fronts in the Fisher equation with degenerate nonlinear diffusion
- Spreading disease: Integro-differential equations old and new.
- The minimal speed of traveling fronts for a diffusive Lotka-Volterra competition model.
- The evolution of dispersal rates in a heterogeneous time-periodic environment
- Integrodifference equations, Allee effects, and invasions
- Spreading speed and linear determinacy for two-species competition models
- On spreading speeds and traveling waves for growth and migration models in a periodic habitat
- The evolution of dispersal
- Spatially-explicit matrix models
- Dispersal and pattern formation in a discrete-time predator-prey model
- Competition in a spatially heterogeneous environment: Modelling the risk of spread of a genetically engineered population
- A short note on short dispersal events
- Analysis of the periodically fragmented environment model. I: Species persistence
- How parasitism affects critical patch-size in a host--parasitoid model: application to the forest tent caterpillar
- Persistence, spread and the drift paradox
- An integrodifference model for biological invasions in a periodically fragmented environment
- Long-Time Behavior of a Class of Biological Models
- Finite Speed of Propagation for the Porous Media Equation
- Spatial Ecology via Reaction‐Diffusion Equations
- Transport equations with resting phases
- Should a Park Be an Island?
- The Effect of Dispersal Patterns on Stream Populations
- Spreading speed and travelling wave solutions of a partially sedentary population
- RANDOM DISPERSAL IN THEORETICAL POPULATIONS
This page was built for publication: Density-dependent dispersal in integrodifference equations
