Global Calderon-Zygmund estimates for irregular double-phase evolution problem with non-divergence data
Abstract
We study irregular double-phase parabolic equations with variable exponents and non-divergence data, \[ ut-div (F(z,∇ u)∇ u )=f(z), z=(x,t)∈ QT:=Ω× (0,T), \] under the homogeneous Dirichlet boundary conditions. Here, Ω⊂ RN, N ≥ 2, is a bounded domain, T>0, \[ F(z,∇ u)=a(z)|∇ u|p(z)-2 + b(z) |∇ u |q(z)-2 \] with given Lipschitz-continuous exponents p,q that satisfy a suitable balance condition. The nonnegative coefficients a(z), b(z) satisfy the inequality a(z)+b(z)>0 in QT, the space and time derivatives of a and b belong to Ld(QT) with some d depending on the data. If \[ f∈ Lσ(QT) for \ σ∈ (2, N+2] and F((·,0),∇ u0)\,|∇ u0|r+2∈ L1(Ω), \] where \(0 r K(N,σ,p,q)\) if \(σ<N+2\), while \(r0\) is arbitrary if \(σ=N+2\), then the problem has a unique strong solution, for which we prove the global transfer of integrability from the initial data and the forcing term to the double-phase flux in the spirit of Calderón-Zygmund theory, higher integrability of the gradient, and the second-order space regularity: \[ split & F((·,t),∇ u(·,t))|∇ u(·,t)|r+2∈ L1(Ω) for a.e. t∈ (0,T), \\ & |∇ u|2(\p(z),q(z)\-1)+r+s∈ L1(QT) for every s∈(0,4N+2), \\ & F(z,∇ u)|∇ u|r+22 ∈ L2(0,T;W1,2(Ω)). split \] The results improve and complement the results in Arora-Shmarev-JGA-2026 and extend them to the full range r ≥ 0.
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