Wave maps on R: Difference between revisions
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* Scaling is s_c = 1/2. | * Scaling is s_c = 1/2. | ||
* LWP in H^s for s > 1/2 [[ | * LWP in H^s for s > 1/2 ([[KeTa1998b]]) | ||
** Proven for s \geq 1 in [[Zh-p]] | ** Proven for s \geq 1 in [[Zh-p]] | ||
** Proven for s > 3/2 by energy methods | ** Proven for s > 3/2 by energy methods. | ||
** One also has LWP in the space L^1_1 [[ | ** One also has LWP in the space L^1_1 ([[KeTa1998b]]). Interpolants of this with the H^s results are probably possible. | ||
** One has ill-posedness for H^{1/2}, and similarly for Besov spaces near H^{1/2} such as B^{1/2,1}_2 [[ | ** One has ill-posedness for H^{1/2}, and similarly for Besov spaces near H^{1/2} such as B^{1/2,1}_2 [[Na1999]], [[Ta2000]]. However, the ill-posedness is not an instance of blowup, only of a discontinuous solution map, and perhaps a weaker notion of solution still exists and is unique. | ||
* GWP in H^s for s>3/4 [[ | * GWP in H^s for s>3/4 [[KeTa1998b]] when the target manifold is a sphere using the [[I-method]]. | ||
** Was proven for s \geq 1 in [[ | ** Was proven for s \geq 1 in [[Zh1999]] for general manifolds | ||
** Was proven for s \geq 2 for general manifolds in [[ | ** Was proven for s \geq 2 for general manifolds in [[Gu1980]], [[LaSh1981]], [[GiVl1982]], [[Sa1988]] | ||
** One also has GWP and scattering in L^1_1 | ** One also has GWP and scattering in L^1_1 ([[KeTa1998b]]). One probably also has asymptotic completeness. | ||
** Scattering fails when the initial velocity is not conditionally integrable [[ | ** Scattering fails when the initial velocity is not conditionally integrable [[KeTa1998b]]. | ||
** It should be possible to improve the s>3/4 result by correction term methods, and perhaps to obtain interpolants with the L^{1,1} result. One should also be able to extend to general manifolds. | ** It should be possible to improve the s>3/4 result by correction term methods, and perhaps to obtain interpolants with the L^{1,1} result. One should also be able to extend to general manifolds. | ||
* ''Remark''<nowiki>: The non-linear term has absolutely no smoothing properties, because of the double derivative in the non-linearity and the lack of dispersion in the one-dimensional case.</nowiki> | * ''Remark''<nowiki>: The non-linear term has absolutely no smoothing properties, because of the double derivative in the non-linearity and the lack of dispersion in the one-dimensional case.</nowiki> | ||
* ''Remark'' | * ''Remark'': The equation is [[completely integrable]] ([[Pm1976]]), but not in the same way as [[KdV]], [[mKdV]] or [[cubic NLS|1D NLS]]. (The additional conserved quantities do not control H^s norms, but rather the pointwise distribution of the energy. Indeed, the energy density itself obeys the free wave equation!) When the target is a symmetric space, homoclinic periodic multisoliton solutions were constructed in [[TeUh-p2]]. | ||
* Remark: When the target manifold is S<sup>2</sup>, the wave map equation is related to the [ | * Remark: When the target manifold is S<sup>2</sup>, the wave map equation is related to the [[sine-Gordon equation]] ([[Pm1976]]). Homoclinic periodic breather solutions were constructed in [[SaSr1996]]. | ||
* When the target is a Lorentzian manifold, local existence for smooth solutions was established in [Cq-p2].A criterion on the target manifold to guarantee global existence of smooth solutions is in [Woo-p]; however if the target manifold is the Lorentz sphere S^{1,n-1} then there is a large class of data which blows up [[Woo-p]]. | * When the target is a Lorentzian manifold, local existence for smooth solutions was established in [[Cq-p2]].A criterion on the target manifold to guarantee global existence of smooth solutions is in [[Woo-p]]; however if the target manifold is the Lorentz sphere S^{1,n-1} then there is a large class of data which blows up [[Woo-p]]. | ||
[[Category:Integrability]] | [[Category:Integrability]] | ||
[[Category:wave]] | [[Category:wave]] | ||
[[Category:Equations]] | [[Category:Equations]] | ||
Revision as of 05:21, 2 August 2006
- Scaling is s_c = 1/2.
- LWP in H^s for s > 1/2 (KeTa1998b)
- Proven for s \geq 1 in Zh-p
- Proven for s > 3/2 by energy methods.
- One also has LWP in the space L^1_1 (KeTa1998b). Interpolants of this with the H^s results are probably possible.
- One has ill-posedness for H^{1/2}, and similarly for Besov spaces near H^{1/2} such as B^{1/2,1}_2 Na1999, Ta2000. However, the ill-posedness is not an instance of blowup, only of a discontinuous solution map, and perhaps a weaker notion of solution still exists and is unique.
- GWP in H^s for s>3/4 KeTa1998b when the target manifold is a sphere using the I-method.
- Was proven for s \geq 1 in Zh1999 for general manifolds
- Was proven for s \geq 2 for general manifolds in Gu1980, LaSh1981, GiVl1982, Sa1988
- One also has GWP and scattering in L^1_1 (KeTa1998b). One probably also has asymptotic completeness.
- Scattering fails when the initial velocity is not conditionally integrable KeTa1998b.
- It should be possible to improve the s>3/4 result by correction term methods, and perhaps to obtain interpolants with the L^{1,1} result. One should also be able to extend to general manifolds.
- Remark: The non-linear term has absolutely no smoothing properties, because of the double derivative in the non-linearity and the lack of dispersion in the one-dimensional case.
- Remark: The equation is completely integrable (Pm1976), but not in the same way as KdV, mKdV or 1D NLS. (The additional conserved quantities do not control H^s norms, but rather the pointwise distribution of the energy. Indeed, the energy density itself obeys the free wave equation!) When the target is a symmetric space, homoclinic periodic multisoliton solutions were constructed in TeUh-p2.
- Remark: When the target manifold is S2, the wave map equation is related to the sine-Gordon equation (Pm1976). Homoclinic periodic breather solutions were constructed in SaSr1996.
- When the target is a Lorentzian manifold, local existence for smooth solutions was established in Cq-p2.A criterion on the target manifold to guarantee global existence of smooth solutions is in Woo-p; however if the target manifold is the Lorentz sphere S^{1,n-1} then there is a large class of data which blows up Woo-p.
