Linear Airy estimates: Difference between revisions

Latest revision as of 14:29, 10 August 2006

The following linear estimates for the Airy equation are known:

If $u\in X^{0,1/2+}$ $u\in X^{0,1/2+}$ on R, then
- u $\in L_{t}^{\infty }L_{x}^{2}$ (energy estimate)
- D_x^{1/4} u is in L^4_t BMO_x (endpoint Strichartz) KnPoVe1993
- D_x u is in L^\infty_x L^2_t (sharp Kato smoothing effect) KnPoVe1993. Earlier versions of this estimate were obtained in Ka1979b, KrFa1983.
- D_x^{-1/4} u is in L^4_x L^\infty_t (Maximal function) KnPoVe1993, KnRu1983
- D_x^{-3/4-} u is in L^2_x L^\infty_t (L^2 maximal function) KnPoVe1993
- Remark: Further estimates are available by Sobolev, differentiation, Holder, and interpolation. For instance:
  - D_x u is in L^2_{x,t} locally in space Ka1979b - use Kato and Holder (can also be proven directly by integration by parts)
  - u is in L^2_{x,t} locally in time - use energy and Holder
  - D_x^{3/4-} u is in L^8_x L^2_t locally in time - interpolate previous with Kato
  - D_x^{1/6} u is in L^6_{x,t} - interpolate energy with endpoint Strichartz (or Kato with maximal)
  - D_x^{1/8} u is in L^8_t L^4_x - interpolate energy with endpoint Strichartz. (In particular, D_x^{1/8} u is also in L^4_{x,t}).
  - u is in L^8_{x,t}- use previous and Sobolev in space
  - If u is in X^{0,1/3+}, then u is in L^4_{x,t} Bo1993b - interpolate previous with the trivial identity X^{0,0} = L^2
  - If u is in X^{0,1/4+}, then D_x^{1/2} u is in L^4_x L^2_t Bo1993b - interpolate Kato with X^{0,0} = L^2
If u is in X^{0,1/2+} on T, then
- u is in L^\infty_t L^2_x (energy estimate). This is also true in the large period limit.
- u is in L^4_{x,t} locally in time (in fact one only needs u in X^{0,1/3} for this) Bo1993b.
- D_x^{-\eps} u is in L^6_{x,t} locally in time. Bo1993b.
- Remark: there is no smoothing on the circle, so one can never gain regularity.
If u is in X^{0,1/2} on a circle with large period \lambda, then
- u is in L^4_{x,t} locally in time, with a bound of \lambda^{0+}.
  - In fact, when u has frequency N, the constant is like \lambda^{0+} (N^{-1/8} + \lambda^{-1/4}), which recovers the 1/8 smoothing effect on the line in L^4 mentioned earlier. CoKeStTkTa2003.

L^6 conjecture

It is conjectured that if u is a free L^2 solution to the Airy equation on $\mathbb {T}$ , then $u$ is in $L_{t,x}^{6}([0,1]\times \mathbb {T} )$ for any $\epsilon >0$ . It is known that the claim holds if u is replaced by $\langle \nabla \rangle ^{-\epsilon }u$ Bo1993b.

L^8 conjecture

It is conjectured that if u is a free L^2 solution to the Airy equation on $\mathbb {T}$ , then $\langle \nabla \rangle ^{-\epsilon }u$ is in $L_{t,x}^{8}([0,1]\times \mathbb {T} )$ for any $\epsilon >0$ . It is known that the epsilon cannot be completely removed Bo1993b.

@@ Line 6: / Line 6: @@
 ** <span class="SpellE">D_x</span> u is in L^\<span class="SpellE">infty_x</span> L^2_t (sharp Kato smoothing effect) [[KnPoVe1993]]. Earlier versions of this estimate were obtained in [[Ka1979b]], [[KrFa1983]].
 ** <span class="SpellE">D_x</span>^{-1/4} u is in L^4_x L^\<span class="SpellE">infty_t</span> (Maximal function) [[KnPoVe1993]], [[KnRu1983]]
-** <span class="SpellE">D_x</span>^{-3/4-} u is in L^2_x L^\<span class="SpellE">infty_t</span> (L^2 maximal function) [[Bibliography#KnPoVe1993|KnPoVe1993]]
+** <span class="SpellE">D_x</span>^{-3/4-} u is in L^2_x L^\<span class="SpellE">infty_t</span> (L^2 maximal function) [[KnPoVe1993]]
 ** ''Remark'': Further estimates are available by Sobolev, differentiation, Holder, and interpolation. For instance:
 *** <span class="SpellE">D_x</span> u is in L^2_{<span class="SpellE">x,t</span>} locally in space [[Ka1979b]] - use Kato and Holder (can also be proven directly by integration by parts)
@@ Line 23: / Line 23: @@
 * If u is in X^{0,1/2} on a circle with large period \lambda, then
 ** <span class="GramE">u</span> is in L^4_{<span class="SpellE">x,t</span>} locally in time, with a bound of \lambda^{0+}.
-*** In fact, when u has frequency N, the constant is like \lambda^{0+} (N<span class="GramE">^{</span>-1/8} + \lambda^{-1/4}), which recovers the 1/8 smoothing effect on the line in L^4 mentioned earlier. [[CoKeStTkTa-p2]].
+*** In fact, when u has frequency N, the constant is like \lambda^{0+} (N<span class="GramE">^{</span>-1/8} + \lambda^{-1/4}), which recovers the 1/8 smoothing effect on the line in L^4 mentioned earlier. [[CoKeStTkTa2003]].
 == L^6 conjecture ==
-It is conjectured that if u is a free L^2 solution to the Airy equation, then <math>u</math> is in <math>L^6_{t,x}([0,1] \times \R)</math> for any <math>\epsilon > 0</math>.  It is known that the claim holds if ''u'' is replaced by <math>\langle \nabla\rangle^{-\epsilon} u</math> [[Bo1993b]].
+It is conjectured that if u is a free L^2 solution to the Airy equation on <math>\mathbb{T}</math>, then <math>u</math> is in <math>L^6_{t,x}([0,1] \times \mathbb{T})</math> for any <math>\epsilon > 0</math>.  It is known that the claim holds if ''u'' is replaced by <math>\langle \nabla\rangle^{-\epsilon} u</math> [[Bo1993b]].
 == L^8 conjecture ==
-It is conjectured that if u is a free L^2 solution to the Airy equation, then <math>\langle \nabla \rangle^{-\epsilon}\rangle u</math> is in <math>L^8_{t,x}([0,1] \times \R)</math> for any <math>\epsilon > 0</math>.  It is known that the epsilon cannot be completely removed [[Bo1993b]].
+It is conjectured that if u is a free L^2 solution to the Airy equation on <math>\mathbb{T}</math>, then <math>\langle \nabla \rangle^{-\epsilon} u</math> is in <math>L^8_{t,x}([0,1] \times \mathbb{T})</math> for any <math>\epsilon > 0</math>.  It is known that the epsilon cannot be completely removed [[Bo1993b]].

Linear Airy estimates: Difference between revisions

Latest revision as of 14:29, 10 August 2006

L^6 conjecture

L^8 conjecture

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