A thorough analysis is performed in a predator-prey reaction-diffusion model
which includes three relevant complex dynamical ingredients: (a) a strong Allee
effect; (b) ratio-dependent functional responses; and (c) transport attributes
given by a diffusion process. As is well-known in the specialized literature,
these aspects capture adverse survival conditions for the prey, predation
search features and non-homogeneous spatial dynamical distribution of both
populations. We look for traveling-wave solutions and provide rigorous results
coming from a standard local analysis, numerical bifurcation analysis, and
relevant computations of invariant manifolds to exhibit homoclinic and
heteroclinic connections and periodic orbits in the associated dynamical system
in R4. In so doing, we present and describe a diverse zoo of traveling wave
solutions; and we relate their occurrence to the Allee effect, the spreading
rates and propagation speed. In addition, homoclinic chaos is manifested via
both saddle-focus and focus-focus bifurcations as well as a Belyakov point. An
actual computation of global invariant manifolds near a focus-focus homoclinic
bifurcation is also presented to enravel a multiplicity of wave solutions in
the model. A deep understanding of such ecological dynamics is therefore
highlighted.Comment: 35 pages, 22 figure