Dispersive Estimates for higher dimensional Schr\"odinger Operators with threshold eigenvalues II: The even dimensional case

Abstract

We investigate L1( Rn) L∞( Rn) dispersive estimates for the Schr\"odinger operator H=-+V when there is an eigenvalue at zero energy in even dimensions n≥ 6. In particular, we show that if there is an eigenvalue at zero energy then there is a time dependent, rank one operator Ft satisfying \|Ft\|L1 L∞ |t|2-n2 for |t|>1 such that \|eitHPac-Ft\|L1 L∞ |t|1-n2,\,\,\,\,\, for |t|>1. With stronger decay conditions on the potential it is possible to generate an operator-valued expansion for the evolution, taking the form align* eitH Pac(H)=|t|2-n2A-2+ |t|1-n2 A-1+|t|-n2A0, align* with A-2 and A-1 mapping L1( Rn) to L∞( Rn) while A0 maps weighted L1 spaces to weighted L∞ spaces. The leading-order terms A-2 and A-1 are both finite rank, and vanish when certain orthogonality conditions between the potential V and the zero energy eigenfunctions are satisfied. We show that under the same orthogonality conditions, the remaining |t|-n2A0 term also exists as a map from L1( Rn) to L∞( Rn), hence eitHPac(H) satisfies the same dispersive bounds as the free evolution despite the eigenvalue at zero.