Construction of Solutions with Extraordinary Gradient Amplification and Localization for Schr\"odinger Equations

Abstract

This paper constructs solutions to linear and nonlinear Schr\"odinger-type equations in two and three spatial dimensions that exhibit prescribed, extraordinary gradient amplification and localization. For any finite time interval [0,T], any prescribed collection of n∈N distinct points on ∂ D, where D is the compact support of the anisotropic coefficients, lower-order terms, or nonlinearities, and any amplitude threshold M>0, we show that one can design smooth initial and/or boundary data such that the spatial gradients of the resulting solutions exceed M in neighborhoods of these points outside D for almost every t∈[0,T]. Moreover, the ratio between the local C1,12-norm of the solution near each prescribed point outside D and the C1,12-norm inside D is bounded from below by M/2 for almost every t∈[0,T]. We further prove that the spatial measure of the regions where the gradient magnitude exceeds M tends to zero as M∞, demonstrating that the amplification phenomenon is highly localized. This effect arises from the structure of the Schr\"odinger-type equation combined with carefully designed input profiles. From a physical perspective, the results provide a deterministic analogue of localization phenomena observed in quantum scattering and Anderson localization. In addition, the observed trade-off between extreme spatial localization and large gradient amplification is fully consistent with the spirit of the Heisenberg uncertainty principle: while the latter is traditionally formulated in a global L2 space--frequency framework, our results offer a complementary deterministic manifestation at the level of localized spatial gradients in Schr\"odinger dynamics.