# The Solvability of a Strongly-Coupled Nonlocal System of Equations

**Authors:** Tadele Mengesha, James M. Scott

arXiv: 1906.10287 · 2019-06-26

## TL;DR

This paper establishes the existence and uniqueness of solutions for a nonlocal, strongly coupled hyperbolic system derived from a nonlocal elasticity model, using semigroup methods and Fourier analysis.

## Contribution

It introduces a novel approach to proving well-posedness of a nonlocal hyperbolic system with a matrix kernel, extending results to $L^p$ spaces for fractional Laplacian kernels.

## Key findings

- Proved $L^2$-solvability of the elliptic system using Fourier transform.
- Established well-posedness of the wave problem via semigroup theory.
- Extended solvability results to $L^p$ spaces for fractional Laplacian kernels.

## Abstract

We prove existence and uniqueness of strong (pointwise) solutions to a linear nonlocal strongly coupled hyperbolic system of equations posed on all of Euclidean space. The system of equations comes from a linearization of a nonlocal model of elasticity in solid mechanics. It is a nonlocal analogue of the Navier-Lam\'e system of classical elasticity. We use a well-known semigroup technique that hinges on the strong solvability of the corresponding steady-state elliptic system. The leading operator is an integro-differential operator characterized by a distinctive matrix kernel which is used to couple differences of components of a vector field. For an operator possessing an asymmetric kernel comparable to that of the fractional Laplacian, we prove the $L^2$-solvability of the elliptic system in a Bessel potential space using the Fourier transform and \textit{a priori} estimates. This $L^2$-solvability together with the Hille-Yosida theorem is used to prove the well posedness of the wave-type time dependent problem. For the fractional Laplacian kernel we extend the solvability to $L^p$ spaces using classical multiplier theorems.

## Full text

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## References

21 references — full list in the complete paper: https://tomesphere.com/paper/1906.10287/full.md

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Source: https://tomesphere.com/paper/1906.10287