The steady states of the dynamical Ender CSTR problem are analysed in terms
of degenerate bifurcation (singularity) theory. Steady-state analysis is u
sed in two ways: (1) as a device to assist in understanding and predicting
complex dynamical behaviour; and (2) as a practical design and operational
tool, by applying the concept of quasi-static parameter variation. In the b
ifurcation analysis, consideration is given to the effects of thermal misma
tching, kinetic mismatching, and variations in the thermal exchange, mass f
lux and heat loss rate parameters, on the structure of the parameter space.
The qualitative equivalence of the bifurcation structure of the kineticall
y matched perfectly coupled adiabatic Ender scheme and the single-reaction
adiabatic CSTR is demonstrated, with reference to the role of the reaction
enthalpy effects. Numerical analysis shows that either kinetic mismatching
of the reactions or imperfect heat exchange may introduce Hopf bifurcations
into the adiabatic system. This is a result that is both philosophically a
nd practically important because it shows that limit cycles are not restric
ted to non-adiabatic thermokinetic systems. The coefficients of thermal exc
hange, mass flux and heat loss are found to induce distortions of the surfa
ce of saddle-node bifurcations (the limit-point shell) through codimension-
2 bifurcations. The steady-state and oscillatory-state degeneracies are dis
cussed with reference to the design and operational implications for a work
ing system.