Luke Denholm
School of Mathematics & Physics, University of Tasmania, Hobart, Australia
Nicholas J. Beeton
School of Mathematics & Physics, University of Tasmania, Hobart, Australia
Lawrence K. Forbes
School of Mathematics & Physics, University of Tasmania, Hobart, Australia
Scott Carver
School of Biological Sciences, University of Tasmania, Hobart, Australia
Ross River Disease is a mosquito-borne viral condition that affects pockets of the Australian human population, and can be debilitating in some instances. The evidence is that the virus reservoirs in marsupials, such as kangaroos, and this may account for the unpredictable outbreaks of the disease in humans. Accordingly, we present here a new model for the dynamics of Ross River Virus (RRV) in populations of mosquitoes and kangaroos. We calculate steady-state populations for the sub-groups in each species and demonstrate that naturally-occurring oscillations in the populations (limit cycles) do not occur. When seasonal forcing of vector populations and kangaroo birth rates is taken into account, however, the model may predict multi-annual outbreaks and chaos, perhaps explaining the unpredictability of some RRV disease epidemics, particularly across southern Australia. Detailed results in this case are presented.