A Class of integrable flows on the space of symmetric matrices

For a given skew symmetric real n x n matrix N , the bracket [X, Y]_N = XNY - YNX defines a Lie algebra structure on the space Sym(n, N ) of symmetric n x n real matrices and hence a corresponding Lie-Poisson structure. The purpose of this paper is to investigate the geometry, integrability, and linearizability of the Hamiltonian system $\dot{{X}}$ = [X², N] , or equivalently in Lax form, the equation $\dot{X}$ = [X, XN + NX] on this space along with a detailed study of the Poisson geometry itself. If N has distinct eigenvalues, it is proved that this system is integrable on a generic symplectic leaf of the Lie-Poisson structure of Sym(n, N ). This is established by finding another compatible Poisson structure.

If N is invertible, several remarkable identifications can be implemented. First, (Sym(n, N ), [.,.]) is Lie algebra isomorphic with the symplectic Lie algebra $\mathfrak{sp}(n,N^{-1})$ associated to the symplectic form on $\mathbb {R}$ ⁿ given by N^-1 . In this case, the system is the reduction of the geodesic flow of the left invariant Frobenius metric on the underlying symplectic group Sp(n, N^-1 ). Second, the trace of the product of matrices defines a non-invariant non-degenerate inner product on Sym(n, N ) which identifies it with its dual. Therefore, Sym(n, N ) carries a natural Lie-Poisson structure as well as a compatible ``frozen bracket" structure. The Poisson diffeomorphism from Sym(n, N ) to $\mathfrak{sp}(n,N^{-1})$ maps our system to a Mischenko-Fomenko system, thereby providing another proof of its integrability if N is invertible with distinct eigenvalues. Third, there is a second ad-invariant inner product on Sym(n, N ); using it to identify Sym(n, N ) with itself and composing it with the dual of the Lie algebra isomorphism with $\mathfrak{sp}(n,N^{-1})$ , our system become a Mischenko-Fomenko system directly on Sym(n, N ). If N is invertible and has distinct eigenvalues, it is shown that this geodesic flow on Sym(n, N ) is linearized on the Prym subvariety of the Jacobian of the spectral curve associated to Lax pair formulation with parameter of the system. If, on the other hand, N has nullity one and distinct eigenvalues in spite of the fact that the system is completely integrable, it is shown that the flow does not linearize on the Jacobian of the spectral curve.

A Class of integrable flows on the space of symmetric matrices

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