Singular Lagrangian torus fibrations on the smoothing of algebraic cones

Abstract: Given a lattice polytope $Q\subset \mathbb{R}^n$, we can consider the cone $\sigma=C(Q)={\lambda(q,1)\in \mathbb{R}^{n+1}|\lambda \in \mathbb{R}{\geq0}, q\in Q} \subset \mathbb{R}^{n+1}$, and the affine toric variety $Y{\sigma}$ associated to $\sigma$. Altmann showed that the versal deformation space of $Y_\sigma$ can be described by the Minkowski decomposition of the polytope $Q$. Under some conditions on $Q$, we can obtain a smooth deformation $Y_\epsilon$ of $Y_\sigma$ using Altmann's result. In this article, we consider $Y_\epsilon$ inside some $\mathbb{C}^N$ and construct a complex fibration on $Y_\epsilon$, with general fibre $(\mathbb{C}^*)^n$ and finite singular fibres described using global coordinates related to the components of the Minkowski decomposition. We construct a singular Lagrangian torus fibration out of the complex fibration. This singular fibration admits a convex base diagram representation with cuts as a natural generalization of base diagrams described by Symington for Almost Toric Fibrations ($\dim=4$). In particular, we obtain a convex base diagram whose image is the dual cone of $C(Q)$. There is a 1-parameter family of monotone Lagrangian tori in each of these fibrations. Using the wall-crossing formula, we describe the potential associated with this family in terms of the Minkowski decomposition of $Q$, recovering the result of Lau, and discuss non-displaceability. We also discuss some other consequences of our results.