Lp-boundedness of wave operators for fourth order Schr\"odinger operators with zero resonances on R3
Abstract
Let H = 2 + V be the fourth-order Schr\"odinger operator on R3 with a real-valued fast-decaying potential V. If zero is neither a resonance nor an eigenvalue of H, then it was recently shown that the wave operators W(H, 2) are bounded on Lp(R3) for all 1 < p < ∞ and unbounded at the endpoints p=1 and p=∞. This paper is to further establish the Lp-boundedness of W(H, 2) that exhibit all types of singularities at the zero energy threshold. We first prove that W(H, 2) are bounded on Lp(R3) for all 1 < p < ∞ in the first kind resonance case, and then proceed to establish for the second kind resonance case that they are bounded on Lp(R3) for all 1 < p < 3, but not if 3 p ∞. In the third kind resonance case, we also show that W(H, 2) are bounded on Lp(R3) for all 1<p<3 and generically unbounded on Lp(3) for any 3 p∞. Moreover, it is also shown that W(H, 2) are bounded on Lp(3) for all 3 p<∞ if in addition H has the zero eigenvalue, but no p-wave zero resonances and all zero eigenfunctions are orthogonal to xixjxkV in L2(3) for all i,j,k=1,2,3 with x=(x1,x2,x3)∈ 3. These results describe precisely the validity of the Lp-boundedness of W(H, 2) in R3 for all types of singularities at the zero energy threshold with some exceptions for the endpoint cases p=1,∞. As an application, Lp-Lq decay estimates are also derived for the fourth-order Schr\"odinger equations and Beam equations with zero resonance singularities.
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