Modelling dispersal of populations and genetic information by finite element methods

This paper shows how biological population dynamic models in the form of partial differential equations can be applied to heterogeneous landscapes. The systems of coupled partial differential equations presented combine dispersal, growth, competition and genetic interactions. The equations belong to the class of reaction diffusion equations and are strongly non-linear. Realistic biological dispersal behaviour is introduced by density dependent diffusion coefficients and chemotaxis terms, which model the active movement along gradients of environmental variables. The resulting non-linear initial boundary value problems are solved for geometries of heterogeneous landscapes, which determine model parameters such as diffusion coefficients, habitat suitability and land use. Geometry models are imported from a geographical information system into a general purpose finite element solver for systems of coupled PDEs. The importance of spatial heterogeneity is demonstrated for management of biological control by sterile males and for risk management of GMO crops.

[1]  Linda R. Petzold,et al.  Using Krylov Methods in the Solution of Large-Scale Differential-Algebraic Systems , 1994, SIAM J. Sci. Comput..

[2]  Otto Richter,et al.  Modelling spatio-temporal dynamics of herbicide resistance , 2002 .

[3]  Elena Litchman,et al.  Algal games: The vertical distribution of phytoplankton in poorly mixed water columns , 2001 .

[4]  James D. Murray Mathematical Biology: I. An Introduction , 2007 .

[5]  Ralf Seppelt,et al.  Flow of genetic information through agricultural ecosystems: a generic modelling framework with application to pesticide-resistance weeds and genetically modified crops , 2004 .

[6]  Richard T. Roush,et al.  Insect Resistance to Transgenic Bt Crops: Lessons from the Laboratory and Field , 2003, Journal of economic entomology.

[7]  Michael F. Goodchild,et al.  Gis and Environmental Modeling: Progress and Research Issues , 1996 .

[8]  Linda R. Petzold,et al.  Numerical solution of initial-value problems in differential-algebraic equations , 1996, Classics in applied mathematics.

[9]  R. Fisher THE WAVE OF ADVANCE OF ADVANTAGEOUS GENES , 1937 .

[10]  K Dietz,et al.  The effect of immigration on genetic control. , 1976, Theoretical population biology.

[11]  Louis J. Gross,et al.  Applied Mathematical Ecology , 1990 .

[12]  Richard J. Gaylord,et al.  Modeling Nature: Cellular Automata Simulations with Mathematica® , 1996 .

[13]  A. Meats,et al.  Dispersion theory and the sterile insect technique: application to two species of fruit fly , 2006 .

[14]  Jochen Albrecht,et al.  Integrated Framework for the Simulation of Biological Invasions in a Heterogeneous Landscape , 2004, Trans. GIS.

[15]  M. Goodchild,et al.  Environmental Modeling with GIS , 1994 .

[16]  M A Lewis,et al.  Waves of extinction from sterile insect release. , 1993, Mathematical biosciences.