Existence and stability of infinite time bubble towers in the energy critical heat equation (1905.13500v1)
Abstract: We consider the energy critical heat equation in $\mathbb Rn$ for $n\ge 7$ $$\left{ \begin{aligned} u_t & = \Delta u+ |u|{\frac 4{n-2}}u \hbox{ in }\ \mathbb Rn \times (0, \infty), \ u(\cdot,0) & = u_0 \ \hbox{ in }\ \mathbb Rn, \end{aligned}\right. $$ which corresponds to the $L2$-gradient flow of the Sobolev-critical energy $$ J(u) = \int_{\mathbb Rn} e[u] , \quad e[u] := \frac 12 |\nabla u|2 - \frac {n-2}{2n} |u|{\frac {2n}{n-2} }. $$ Given any $k\ge 2$ we find an initial condition $u_0$ that leads to sign-changing solutions with {\em multiple blow-up at a single point} (tower of bubbles) as $t\to +\infty$. It has the form of a superposition with alternate signs of singularly scaled {\em Aubin-Talenti solitons}, $$ u(x,t) = \sum_{j=1}k (-1){j-1} {\mu_j{-\frac {n-2}2}} U \left( \frac {x}{\mu_j} \right)\, +\, o(1) \quad\hbox{as } t\to +\infty $$ where $U(y)$ is the standard soliton $ U(y) = % (n(n-2)){\frac 1{n-2}} \alpha_n\left ( \frac 1{1+|y|2}\right){\frac{n-2}2}$ and $$\mu_j(t) = \beta_j t{- \alpha_j}, \quad \alpha_j = \frac 12 \Big ( \, \left( \frac{n-2}{n-6}\right){j-1} -1 \Big). $$ Letting $\delta_0$ the Dirac mass, we have energy concentration of the form $$ e[ u(\cdot, t)]- e[U] \rightharpoonup (k-1) S_n\,\delta_{0} \quad\hbox{as } t\to +\infty $$ where $S_n=J(U)$. The initial condition can be chosen radial and compactly supported. We establish the codimension $k+ n (k-1)$ stability of this phenomenon for perturbations of the initial condition that have space decay $u_0(x) =O( |x|{-\alpha})$, $\alpha > \frac {n-2}2$, which yields finite energy of the solution.