# On stable solutions for boundary reactions: a De Giorgi-type result in   dimension 4+1

**Authors:** Alessio Figalli, Joaquim Serra

arXiv: 1705.02781 · 2017-05-09

## TL;DR

This paper proves a De Giorgi-type conjecture for boundary reactions involving the half-Laplacian in dimension 4, showing that all bounded stable solutions are one-dimensional profiles, extending the understanding of stability and symmetry in nonlocal PDEs.

## Contribution

It establishes the De Giorgi conjecture for boundary reactions with the half-Laplacian in dimension 4, demonstrating that stable solutions are necessarily one-dimensional.

## Key findings

- All bounded stable solutions are one-dimensional profiles.
- The result confirms the De Giorgi conjecture for half-Laplacian boundary reactions in dimension 4.
- Analogous to stable minimal surfaces being planes in $\

## Abstract

We prove that every bounded stable solution of \[ (-\Delta)^{1/2} u + f(u) =0 \qquad \mbox{in }\mathbb R^3\] is a 1D profile, i.e., $u(x)= \phi(e\cdot x)$ for some $e\in \mathbb S^2$, where $\phi:\mathbb R\to \mathbb R$ is a nondecreasing bounded stable solution in dimension one. This proves the De Giorgi conjecture in dimension $4$ for the half-Laplacian. Equivalently, we give a positive answer to the De Giorgi conjecture for boundary reactions in $\mathbb R^{d+1}_+=\mathbb R^{d+1}\cap \{x_{d+1}\geq 0\}$ when $d = 4$, by proving that all critical points of $$ \int_{\{x_{d+1\geq 0}\}} \frac12 |\nabla U|^2 \,dx\, dx_{d+1} + \int_{\{x_{d+1}=0\}} \frac 1 4 (1-U^2)^2 \,dx $$ that are monotone in $\mathbb R^d$ (that is, up to a rotation, $\partial_{x_d} U>0$) are one dimensional.   Our result is analogue to the fact that stable embedded minimal surfaces in $\mathbb R^3$ are planes. Note that the corresponding result about stable solutions to the classical Allen-Cahn equation (namely, when the half-Laplacian is replaced by the classical Laplacian) is still open.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1705.02781/full.md

## References

32 references — full list in the complete paper: https://tomesphere.com/paper/1705.02781/full.md

---
Source: https://tomesphere.com/paper/1705.02781