Integrable deformations of Rikitake systems, Lie bialgebras and bi-Hamiltonian structures.

Integrable deformations of a class of Rikitake dynamical systems are constructed by deforming their underlying Lie–Poisson Hamiltonian structures, which are considered linearizations of Poisson–Lie structures on certain (dual) Lie groups. By taking into account that there exists a one-to one correspondence between Poisson–Lie groups and Lie bialgebra structures, a number of deformed Poisson coalgebras can be obtained, which allow the construction of integrable deformations of coupled Rikitake systems. Moreover, the integrals of the motion for these coupled systems can be explicitly obtained by means of the deformed coproduct map. The same procedure can be also applied when the initial system is bi-Hamiltonian with respect to two different Lie–Poisson algebras. In this case, to preserve a bi-Hamiltonian structure under deformation, a common Lie bialgebra structure for the two Lie–Poisson structures has to be found. Coupled dynamical systems arising from this bi-Hamiltonian deformation scheme are also presented, and the use of collective 'cluster variables', turns out to be enlightening in order to analyse their dynamical behaviour. As a general feature, the approach here presented provides a novel connection between Lie bialgebras and integrable dynamical systems. • Integrable deformations of dynamical systems are constructed through Lie bialgebras. • Deformed integrals of the motion can be directly obtained. • Integrable deformations of Rikitake dynamical systems are presented. • Bi-Hamiltonian systems can be also deformed under certain compatibility constraints. • Coupled systems are constructed by making use of Poisson–Lie group structures. [ABSTRACT FROM AUTHOR]