I saw several papers that without proof accept the fact "Short time existence on nonlinear parabolic PDE" is there any affirmative proof of this fact? in which book we have this fact, the number of page and number of theorem ?
Remember to vote up questions/answers you find interesting or helpful (requires 15 reputation points)
|
5
6
|
|
||||||||
|
|
6
|
This is kind of meta-theorem. It has several version, and if someone was willing to write one theorem containing all the situations, it would be unreadible. The fully non-linear case (example $\partial_t u=\det(\nabla^2u)$ with $u(t=0,\cdot)$ convex, it is really advanced. In the quasilinear case (example $\partial_t u={\rm div}(|\nabla|^{p-1}\nabla u)$, it is still complicated, but several books treat it extensively. The semi-linear case $\partial_tu+Lu=f(u,\nabla u)$, where $L$ is an elliptic linear operator (like the Laplacian $-\Delta$), has a rather simple philosophy. One follows the guidelines of the Cauchy-Lipschitz theory for ODEs. If $a\in X$ is the initial data, one rewrites the Cauchy problem as an integral equation $$u(t)=e^{-tL}a+\int_0^t e^{(s-t)L}f(u(s),\nabla u(s))ds=:Nu(t).$$ When $T>0$ is small enough and the Banach space $X$ is appropriate, one proves that $N$ is a contraction in some ball $B(a;r)$ of $C(0,T;X)$. Then Picard's theorem tells that there is a unique fixed point $u$ ; this is the local solution. |
||||||
|
You can accept an answer to one of your own questions by clicking the check mark next to it. This awards 15 reputation points to the person who answered and 2 reputation points to you.
|
-1
|
Dear Denis Serre, can you please name some good references. |
||||||||
|
