Modified Korteweg-de Vries on R: Difference between revisions

The local and global well-posedness theory for the modified Korteweg-de Vries equation on the line and half-line is as follows.

• Scaling is s_c = -1/2.
• LWP in H^s for s >= 1/4 KnPoVe1993
  • Was shown for s>3/2 in GiTs1989
  • This is sharp in the focusing case KnPoVe2001, in the sense that the solution map is no longer uniformly continuous for s < 1/4.
    • This has been extended to the defocusing case in CtCoTa-p, by a high-frequency approximation of mKdV by cubic NLS. (This high frequency approximation has also been utilized in Sch1998).
    • Below 1/4 the solution map was known to not be C^3 in Bo1993b, Bo1997.
  • The same result has also been established for the half-line CoKn-p, assuming boundary data is in H^{(s+1)/3} of course.
  • Global weak solutions in L^2 were constructed in Ka1983. Thus in L^2 one has global existence but no uniform continuity.
  • Uniqueness is also known when the initial data lies in the weighted space <x>^{3/8} u_0 in L^2 GiTs1989
  • LWP has also been demonstrated when <xi>^s hat(u_0) lies in L^{r\u2019} for 4/3 < r <= 2 and s >= ½ - 1/2r Gr-p4
• GWP in H^s for s > 1/4 CoKeStTkTa2003, via the KdV theory and the Miura transform, for both the focussing and defocussing cases.
  • Was proven for s>3/5 in FoLiPo1999
  • Is implicit for s >= 1 from KnPoVe1993
  • On the half-line GWP is known when s >= 1 and the boundary data is in H^{11/12}, assuming compatibility and small L^2 norm CoKn-p
  • GWP for smooth data can also be achieved from inverse scattering methods BdmFsShp-p; the same approach also works on an interval BdmShp-p.
  • Solitons are asymptotically H^1 stable MtMe-p3, MtMe-p