Muckenhoupt-weighted Lq(Lp) boundedness for time-space fractional nonlocal operators

Abstract

We develop a weighted mixed-norm Lq(Lp)-estimates for solutions to fractional evolution equations of the form \[ ∂tα w(t,x) = φ() w(t,x) + h(t,x), w(0,·) = w0, t > 0, \; x ∈ Rd, \] where ∂tα denotes the Caputo derivative of α ∈ (0,1) and φ() is a nonlocal operator associated with a Bernstein function φ. For all p, q ∈ (1, ∞) and γ ∈ R, we prove the estimate align* &\| ∂tα w \|Lq(0,T,μ2dt; Hφ,γp(μ1)) + \| φ() w \|Lq(0,T,μ2dt; Hφ,γp(μ1)) \\ &≤ C ( \| h \|Lq(0,T,μ2dt; Hφ,γp(μ1)) + \| w0 \|Nα,p,φ ), align* where μ1∈ Ap(Rd) and μ2∈ Aq(R) are Muckenhoupt weights, and Nα,p,φ is a Banach space characterizing admissible initial data. In particular, when μ2 1 and α q>1, Nα,p,φ coincides with the weighted Besov space Bφ,γ+2-2α qp,q(μ1). The analysis employs tools from harmonic analysis, including the Fefferman--Stein inequality, Hardy-Littlewood maximal estimates in weighted mixed-norm spaces, and sharp function methods for bounding solution operators. These results extend and unify previous work by K.~H.~Kim et al, providing a general analytic framework for weighted Lq(Lp)-theory of time-space nonlocal evolution equations.