English

Multi-term fractional linear equations modeling oxygen subdiffusion through capillaries

Analysis of PDEs 2026-02-13 v1 Numerical Analysis Numerical Analysis

Abstract

For 0<ν2<ν110<\nu_2<\nu_1\leq 1, we analyze a linear integro-differential equation on the space-time cylinder Ω×(0,T)\Omega\times(0,T) in the unknown u=u(x,t)u=u(x,t) Dtν1(ϱ1u)Dtν2(ϱ2u)L1uKL2u=f\mathbf{D}_{t}^{\nu_1}(\varrho_{1}u)-\mathbf{D}_{t}^{\nu_2}(\varrho_2 u)-\mathcal{L}_{1}u-\mathcal{K}*\mathcal{L}_{2}u =f where Dtνi\mathbf{D}_{t}^{\nu_i} are the Caputo fractional derivatives, ϱi=ϱi(x,t)\varrho_i=\varrho_i(x,t) with ϱ1μ0>0\varrho_1\geq \mu_0>0, Li\mathcal{L}_{i} are uniform elliptic operators with time-dependent smooth coefficients, K\mathcal{K} is a summable convolution kernel, and ff is an external force. Particular cases of this equation are the recently proposed advanced models of oxygen transport through capillaries. Under suitable conditions on the given data, the global classical solvability of the associated initial-boundary value problems is addressed. To this end, a special technique is needed, adapting the concept of a regularizer from the theory of parabolic equations. This allows us to remove the usual assumption about the nonnegativity of the kernel representing fractional derivatives. The problem is also investigated from the numerical point of view.

Keywords

Cite

@article{arxiv.2210.05009,
  title  = {Multi-term fractional linear equations modeling oxygen subdiffusion through capillaries},
  author = {Vittorino Pata and Sergii Siryk and Nataliya Vasylyeva},
  journal= {arXiv preprint arXiv:2210.05009},
  year   = {2026}
}
R2 v1 2026-06-28T03:11:31.286Z