The anisotropic Calder{ó}n problem on 3-dimensional conformally St{ä}ckel manifolds

Abstract: Conformally St{\"a}ckel manifolds can be characterized as the class of n-dimensional pseudo-Riemannian manifolds (M, G) on which the Hamilton-Jacobi equation G($\nabla$u, $\nabla$u) = 0 for null geodesics and the Laplace equation --$\Delta$ G $\psi$ = 0 are solvable by R-separation of variables. In the particular case in which the metric has Riemannian signature, they provide explicit examples of metrics admitting a set of n--1 commuting conformal symmetry operators for the Laplace-Beltrami operator $\Delta$ G. In this paper, we solve the anisotropic Calder{\'o}n problem on compact 3-dimensional Riemannian manifolds with boundary which are conformally St{\"a}ckel, that is we show that the metric of such manifolds is uniquely determined by the Dirichlet-to-Neumann map measured on the boundary of the manifold, up to dieomorphims that preserve the boundary.