A maximal Lp-regularity theory to initial value problems with time measurable nonlocal operators generated by additive processes

Abstract

Let Z=(Zt)t≥0 be an additive process with a bounded triplet (0,0,t)t≥0. Suppose that for any Schwartz function on Rd whose Fourier transform is in Cc∞(Bcs Bcs-1 ), there exist positive constants N0, N1, and N2 such that equation* ∫Rd|E[(x+r-1Zt)]|dx≤ N0 e- N1 ts(r), ∀ (r,t)∈(0,1)×[0,T], equation* and \|μ(r-1D)\|L1(Rd)≤ N2s(r), ∀ r∈(0,1). where s is a scaling function (Definition 2.4), cs is a positive constant related to s, μ is a symmetric L\'evy measure on Rd, μ(r-1D)(x)= F-1 [ μ(r-1) F[]](x) and μ():=∫Rd(eiy·-1-iy· 1|y|≤ 1)μ(dy). In this paper, we establish the Lp-solvability to the initial value problem equation ∂ u∂ t(t,x)=AZ(t)u(t,x), u(0,·)=u0, (t,x)∈(0,T)×Rd, equation In other words, there exists a unique solution u to equation satisfying \|u\|Lq((0,T);Hpμ;γ(Rd))≤ N\|u0\|Bp,qs;γ-2q(Rd), where N is independent of u and u0, and the spaces Bp,qs;γ-2q(Rd) and Hpμ;γ(Rd) are scaled Besov spaces (see Definition 2.8) and generalized Bessel potential spaces (see Definition 2.3), respectively.