Integrable Hamiltonian systems on the symplectic realizations of e(3)*

Abstract

The phase space of a gyrostat with a fixed point and a heavy top is the Lie-Poisson space e(3)* R3× R3 dual to the Lie algebra e(3) of Euclidean group E(3). One has three naturally distinguished Poisson submanifolds of e(3)*: (i) the dense open submanifold R3× R3⊂ e(3)* which consists of all 4-dimensional symplectic leaves (2>0); (ii) the 5-dimensional Poisson submanifold of R3× R3 defined by J· = μ ||||; (iii) the 5-dimensional Poisson submanifold of R3× R3 defined by 2 = 2, where R3:= R3 \0\, (J, )∈ R3× R3 e(3)* and < 0 , μ are some fixed real parameters. Basing on the U(2,2)-invariant symplectic structure of Penrose twistor space we find full and complete E(3)-equivariant symplectic realizations of these Poisson submanifolds which are 8-dimensional for (i) and 6-dimensional for (ii) and (iii). As a consequence of the above Hamiltonian systems on e(3)* lift to the ones on the above symplectic realizations. In such a way after lifting integrable cases of gyrostat with a fixed point, as well as of heavy top, we obtain a large family of integrable Hamiltonian systems on the phase spaces defined by these symplectic realizations.

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