# Semi-classical states for fractional Choquard equations with decaying   potentials

**Authors:** Yinbin Deng, Shuangjie Peng, Xian Yang

arXiv: 2302.11841 · 2023-02-24

## TL;DR

This paper investigates the existence and behavior of semi-classical states for fractional Choquard equations with decaying potentials, employing variational, penalized, and comparison methods to handle nonlocal terms and decay conditions.

## Contribution

It introduces new existence results for fractional Choquard equations with decaying potentials, using novel penalized techniques and comparison principles for nonlocal operators.

## Key findings

- Solutions concentrate at potential minima as epsilon approaches zero.
- Established regularity, positivity, and asymptotic behavior of solutions.
- Proved nonexistence under certain conditions, indicating optimal assumptions.

## Abstract

This paper deals with the following fractional Choquard equation $$\varepsilon^{2s}(-\Delta)^su +Vu=\varepsilon^{-\alpha}(I_\alpha*|u|^p)|u|^{p-2}u\ \ \ \mathrm{in}\ \mathbb{R}^N,$$ where $\varepsilon>0$ is a small parameter, $(-\Delta)^s$ is the fractional Laplacian, $N>2s$, $s\in(0,1)$, $\alpha\in\big((N-4s)_{+}, N\big)$, $p\in[2, \frac{N+\alpha}{N-2s})$, $I_\alpha$ is a Riesz potential, $V\in C\big(\mathbb{R}^N, [0, +\infty)\big)$ is an electric potential. Under some assumptions on the decay rate of $V$ and the corresponding range of $p$, we prove that the problem has a family of solutions $\{u_\varepsilon\}$ concentrating at a local minimum of $V$ as $\varepsilon\to 0$. Since the potential $V$ decays at infinity, we need to employ a type of penalized argument and implement delicate analysis on the both nonlocal terms to establish regularity, positivity and asymptotic behaviour of $u_\varepsilon$, which is totally different from the local case. As a contrast, we also develop some nonexistence results, which imply that the assumptions on $V$ and $p$ for the existence of $u_\varepsilon$ are almost optimal. To prove our main results, a general strong maximum principle and comparison function for the weak solutions of fractional Laplacian equations are established. The main methods in this paper are variational methods, penalized technique and some comparison principle developed in this paper.

## Full text

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## References

35 references — full list in the complete paper: https://tomesphere.com/paper/2302.11841/full.md

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Source: https://tomesphere.com/paper/2302.11841