Global-in-time Strichartz estimates and cubic Schr\"odinger equation in a conical singular space

Abstract

In this paper, we study Strichartz estimates for the Schr\"odinger equation on a metric cone X, where X=C(Y)=(0,∞)r× Y and the cross section Y is a (n-1)-dimensional closed Riemannian manifold (Y,h). For the metric g on X given by g=dr2+r2h, let g be the positive Friedrichs extension Laplacian on X and V=V0 r-2 where V0∈∞(Y) is a real function such that the operator P:=h+V0+(n-2)2/4 is a strictly positive operator on L2(Y). We establish the full range of global-in-time Strichartz estimates without loss for the Schr\"odinger equation associated with the operator V=g+V0 r-2 including the endpoint estimate both in homogeneous and inhomogeneous cases. A new finding reveals that the range of admissible pairs at Hs-level is influenced by the smallest eigenvalue of the operator P. This additionally proves the conjecture in Wang [Ann. Inst. Fourier 2006] and generalizes the results of Ford [Comm. Math. Phys. 2010] and Baskin-Marzuola-Wunsch [Contemp. Math. 2014]. As an application, we show the well-posedness theory and scattering theory for the Schr\"odinger equation with a cubic nonlinearity on this setting which verifies a conjecture in Baskin-Marzuola-Wunsch [Contemp. Math. 2014].