Allee effect in population dynamics has a major impact in suppressing the
paradox of enrichment through global bifurcation, and it can generate highly
complex dynamics. The influence of the reproductive Allee effect, incorporated
in the prey's growth rate of a prey-predator model with Beddington-DeAngelis
functional response, is investigated here. Preliminary local and global
bifurcations are identified of the temporal model. Existence and non-existence
of heterogeneous steady-state solutions of the spatio-temporal system are
established for suitable ranges of parameter values. The spatio-temporal model
satisfies Turing instability conditions, but numerical investigation reveals
that the heterogeneous patterns corresponding to unstable Turing eigen modes
acts as a transitory pattern. Inclusion of the reproductive Allee effect in the
prey population has a destabilising effect on the coexistence equilibrium. For
a range of parameter values, various branches of stationary solutions including
mode-dependent Turing solutions and localized pattern solutions are identified
using numerical bifurcation technique. The model is also capable to produce
some complex dynamic patterns such as travelling wave, moving pulse solution,
and spatio-temporal chaos for certain range of parameters and diffusivity along
with appropriate choice of initial conditions Judicious choices of
parametrization for the Beddington-DeAngelis functional response help us to
infer about the resulting patterns for similar prey-predator models with
Holling type-II functional response and ratio-dependent functional response