Scaling invariance for Hartree equation

Question

Consider generalized Hartree Equation

$ i \partial_t u + \Delta u + \left( \frac{1}{|x|^{\gamma}} \ast |u|^p \right)|u|^{p-2}u, \quad u(x, 0)=u_0(x)$ where $0<\gamma<d, p\geq 2, u(x,t)\in \mathbb C.$

When $p=2$ $-$ classical Hartree equation.

Scaling invariance: if $u(t,x)$ solves GHE, then so does $ u_{\lambda}(t,x)= \lambda^{\frac{d-\gamma +2}{2(p-1)}} u (\lambda^2 t, \lambda x)$ also.

My question is: What is the scaling invariance for fractional generalized Hartree equation: $ i \partial_t u - (- \Delta)^{\alpha/2} u + \left( \frac{1}{|x|^{\gamma}} \ast |u|^p \right)|u|^{p-2}u, \quad u(x, 0)=u_0(x)$

Answer 1

substitution of $u_\mu(t,x)=\text{constant}\times u(\mu^\alpha t,\mu x)$ in the fractional GHE shows that this is a solution if $\text{constant}=\mu^{\frac{d-\gamma+\alpha}{2(p-1)}}$, so the scale invariance relation is $$u_\mu(t,x)=\mu^{\frac{d-\gamma+\alpha}{2(p-1)}}u(\mu^\alpha t,\mu x).$$