The p-boundedness of wave operators for the fourth order Schr\"odinger operators on the lattice Z
Abstract
This paper investigates the p boundedness of wave operators W(H,2) associated with discrete fourth-order Schr\"odinger operators H = 2 + V on the lattice Z, where (φ)(n)=φ(n+1)+φ(n-1)-2φ(n), n∈Z, and V(n) is a real-valued potential on Z. Under suitable decay assumptions on V (depending on the types of zero resonance of H), we show that the wave operators W(H, 2) are bounded on p(Z) for all 1 < p < ∞: \|W(H, 2) f\|p(Z) \|f\|p(Z). In particular, if both thresholds 0 and 16 are regular points of H, we prove that W(H, 2) are neither bounded on the endpoint space 1(Z) nor on ∞(Z). We remark that the proof of these bounds relies fundamentally on the asymptotic expansions of the resolvent of H near the thresholds 0 and 16, and on the theory of discrete singular integrals on the lattice. As applications, we derive the following sharp p-p' decay estimates for solutions to the discrete beam equation with a parameter a∈ R on the lattice Z: \| cos(t H+a2)Pac(H)\|p→p'+\| sin(t H+a2)t H+a2Pac(H)\|p→p'|t|-13(1p-1p'), t≠0, where 1<p 2, p' is the conjugated index of p and Pac(H) denotes the spectral projection onto the absolutely continuous spectrum space of H.
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