Quartic NLW/NLKG: Difference between revisions

Latest revision as of 07:08, 2 August 2006

Scaling is $s_{c}=d/2-2/3$ .
For $d>2$ LWP is known for $s\geq d/2-2/3$ by Strichartz estimates. This is sharp by scaling argumentsin both the focusing and defocusing cases CtCoTa-p2
For $d=2$ $d=2$ LWP is known for $s\geq 5/12$ $s\geq 5/12$ by Strichartz estimates. This is sharp by concentration arguments in the focusing case; the defocusing case is open.
- In the defocusing case one has GWP for $s>2/3$ Fo-p
For $d=1$ one has LWP for $s\geq 1/4$ by energy estimates and Sobolev (solution is in $L_{x}^{4}$ ). Below this regularity one cannot even make sense of the solution as a distribution.

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 * Scaling is <math>s_c = d/2 - 2/3</math>.
-* For <math>d>2</math> LWP is known for <math>s \geq d/2 - 2/3</math> by Strichartz estimates. This is sharp by scaling argumentsin both the focusing and defocusing cases [CtCoTa-p2]
+* For <math>d>2</math> LWP is known for <math>s \geq d/2 - 2/3</math> by Strichartz estimates. This is sharp by scaling argumentsin both the focusing and defocusing cases [[CtCoTa-p2]]
 * For <math>d=2</math> LWP is known for <math>s \geq 5/12</math> by Strichartz estimates. This is sharp by concentration arguments in the focusing case; the defocusing case is open.
-** In the defocusing case one has GWP for <math>s > 2/3</math> [Fo-p]
+** In the defocusing case one has GWP for <math>s > 2/3</math> [[Fo-p]]
 * For <math>d=1</math> one has LWP for <math>s\geq 1/4</math> by energy estimates and Sobolev (solution is in <math>L^4_x</math>). Below this regularity one cannot even make sense of the solution as a distribution.
+[[Category:Wave]]
-----   [[Category:Equations]]
+[[Category:Equations]]