Finite-Time Singularities of Lagrangian Mean Curvature Flow with Quantitatively Precise Dynamics
Abstract
For each integer K≥2 when n≥4, and for K=2,3,4 when n=3, we construct an almost-calibrated Lagrangian mean curvature flow LK(t) in Cn, starting from initial data arbitrarily close to being special Lagrangian, which develops a finite-time Type II singularity at time T with the explicit curvature blow up rate \[ LK(t) |ALK(t)| (T-t)-K/2 as t T . \] The tangent flow at the singularity is a transverse pair of cohomogeneity-one special Lagrangian cones, while the Type II blow-up limit is a smooth cohomogeneity-one special Lagrangian desingularization. This gives a quantitative construction of Type II blow-up for a fully nonlinear parabolic PDE arising from cohomogeneity-one Lagrangian mean curvature flow. Our construction is based on a modulation analysis around a shrinking family of cohomogeneity-one special Lagrangian desingularizations, using the perturbative spectral theory developed in the companion paper.
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