Existence of the gauge for fractional Laplacian Schr\"odinger operators

Abstract

Let ⊂eq Rn be an open set, where n ≥ 2. Suppose ω is a locally finite Borel measure on . For α ∈ (0,2), define the fractional Laplacian (- )α/2 via the Fourier transform on Rn, and let G be the corresponding Green's operator of order α on . Define T(u) = G(u ω). If T L2(ω) → L2 (ω) <1, we obtain a representation for the unique weak solution u in the homogeneous Sobolev space Lα/2, 20 () of \[ (-)α/2 u = u ω + \,\,\, on \,\,\, , \,\,\, u=0 \,\,\, on \,\,\, c, \] for in the dual Sobolev space L-α/2, 2 (). If is a bounded C1,1 domain, this representation yields matching exponential upper and lower pointwise estimates for the solution when = . These estimates are used to study the existence of a solution u1 (called the "gauge") of the integral equation u1=1+G(u1 ω) corresponding to the problem \[ (-)α/2 u = u ω \,\,\, on \,\,\, , \,\,\, u ≥ 0 \,\,\, on \,\,\, , \,\,\, u=1 \,\,\, on \,\,\, c . \] We show that if T <1, then u1 always exists if 0<α <1. For 1 ≤ α <2, a solution exists if the norm of T is sufficiently small. We also show that the condition T <1 does not imply the existence of a solution if 1 < α <2.