# Mixed linear fractional boundary value problems

**Authors:** Ifan Johnston, Vassili Kolokoltsov

arXiv: 1908.03158 · 2019-09-04

## TL;DR

This paper derives two-sided estimates for the Green's function of fractional boundary value problems involving mixed Caputo derivatives and diffusion operators, extending to multiple fractional derivatives.

## Contribution

It provides explicit estimates for Green's functions in mixed fractional boundary value problems, including cases with multiple fractional derivatives, advancing analytical understanding.

## Key findings

- Two-sided estimates for Green's functions are established.
- The approach extends to problems with multiple fractional derivatives.
- Results facilitate analysis of fractional PDEs with boundary conditions.

## Abstract

In this article we obtain two-sided estimates for the Greens function of fractional boundary value problems on $\mathbb R_+ \times \mathbb R_+ \times \mathbb R^d$ of the form \[(-{}_{t_1}D^\beta_{0+*} - {}_{t_2}D^\gamma_{0+*})u(t_1, t_2, x) = L_{x}u(t_1, t_2, x),\] with some prescribed boundary functions on the boundaries $\{0\} \times \mathbb R_+ \times \mathbb R^d$ and $\mathbb R_+ \times\{0\}\times \mathbb R^d$. The operators ${}_{t_1}D^\beta$ and ${}_{t_1}D^\gamma$ are Caputo fractional derivatives of order $\beta, \gamma \in (0, 1)$ and $L_{x}$ is the generator of a diffusion semigroup: $L_x= \nabla \cdot(a(x) \nabla)$ for some nice function $a(x)$. The Greens function of such boundary value problems are decomposed into its components along each boundary, giving rise to a natural extension to the case involving $k \geq 2$ number of fractional derivatives on the left hand side.

## Full text

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Source: https://tomesphere.com/paper/1908.03158