Abstract
We study anti-symmetric solutions about the hyperplane
$\{x_n=0\}$
for the following fractional Hardy–Hénon system:
\[ \left\{\begin{array}{@{}ll} (-\Delta)^{s_1}u(x)=|x|^\alpha v^p(x), & x\in\mathbb{R}_+^n, \\ (-\Delta)^{s_2}v(x)=|x|^\beta u^q(x), & x\in\mathbb{R}_+^n, \\ u(x)\geq 0, & v(x)\geq 0,\ x\in\mathbb{R}_+^n, \end{array}\right. \]
where
$0< s_1,s_2<1$
,
$n>2\max \{s_1,s_2\}$
. Nonexistence of anti-symmetric solutions are obtained in some appropriate domains of
$(p,q)$
under some corresponding assumptions of
$\alpha,\beta$
via the methods of moving spheres and moving planes. Particularly, for the case
$s_1=s_2$
, one of our results shows that one domain of
$(p,q)$
, where nonexistence of anti-symmetric solutions with appropriate decay conditions at infinity hold true, locates at above the fractional Sobolev's hyperbola under appropriate condition of
$\alpha, \beta$
.
Publisher
Cambridge University Press (CUP)
Reference37 articles.
1. Global and local behavior of positive solutions of nonlinear elliptic equations
2. The maximum principles for fractional Laplacian equations and their applications
3. An integral equation on half space
4. A priori estimates and blow-up of solutions to nonlinear partial differential equations and inequalities;Mitidieri;Tr. Mat. Inst. Steklova,2001
5. Liouville-type theorems and bounds of solutions for Hardy–Hénon elliptic systems;Phan;Adv. Differ. Equ,2012