Schrödinger-Type Evolution Equations in Lp(Ω)

In this paper I prove a L p &L p estimate for the solutions to the one-dimensional Schro dinger equation with a potential in L 1 # where in the generic case #>3Â2 and in the exceptional case (i.e., when there is a half-bound state of zero energy) #>5Â2. I use this estimate to construct the scatterin

We present a general technique for constructing nonlocal transparent boundary conditions for one-dimensional Schro ¨dinger-type solution of (1) only in a finite subdomain of ⍀ in order to equations. Our method supplies boundary conditions for theexamine the time evolution in the surrounding of a spe

Orthogonal coordinate systems with helical geometry are constructed in euclidean 3-space and the Schrodinger equations in these coordinate systems are obtained. Of the two helical coordinate systems discussed, the external system consists of flat surfaces while the internal system consists of surfac

In the following, criteria will be obtained for the differential equation to be oscillatory a t x = 00 or x = 0. We assume that the potential q(x) is a real-valued and continuous function on Rn \ [ O ) . A bounded domain G 2 Itn is said to be a nodal domain of equation (1) if there exists a non-triv

## Abstract We consider the numerical solution of the time‐dependent Schrödinger equation in ℝ^3^. An artificial boundary is introduced to obtain a bounded computational domain. On the given artificial boundary the exact boundary condition and a series of approximating boundary conditions are const