Project A9 • Spectral methods for dispersive equations (7/2015 - 6/2019)

Principal investigators

  PD Dr. Peer Kunstmann (7/2015 - 6/2019)
  Prof. Dr. Lutz Weis (7/2015 - 6/2019)

Project summary

In recent years, dispersive equations, such as the nonlinear Schrödinger equation or the nonlinear wave equation, have been studied on increasingly more general domains, manifolds, and graphs. Methods from spectral theory were therefore needed to support the classical harmonic analysis arguments. Furthermore, by randomizing the spectral decomposition of the Laplacian, J. Bourgain introduced probabilistic methods to prove wellposedness results in supercritical cases and to construct invariant (Gibbs) measures. In order to advance the theory of dispersive equations in random environments, these methods are currently being adapted to stochastic Schrödinger and wave equations by extending the recent progress on deterministic equations to their stochastic counterpart.

Based on our work on spectral theoretical formulations of the Littlewood–Paley theory, on random sum techniques in operator theory, and on our extension of stochastic analysis estimates such as Burkholder–Davis–Gundy inequalities and estimates for stochastic convolutions in the infinite dimensional \(L^p\)-setting, which are also based on functional calculus techniques, we will pursue the following goals:

  • Investigate further the possibility of obtaining spectrally localized dispersive estimates directly from the spectral data of a selfadjoint operator \(A\), Gaussian bounds, and oscillatory integral representations for operator-valued functions. This will lead to Strichartz estimates, possibly with "loss of derivatives", and a corresponding wellposedness theory for nonlinear equations in this framework.

  • Extend the random Sobolev embeddings for compact Riemmanian manifolds of N. Burq and G. Lebeau (initiated by J. Bourgain's work) to further classes of selfadjoint operators, particularly in "infinite volume" settings. Then prove wellposedness results for a large set of rough initial values.

  • Adapt the very versatile method of M. Keel and T. Tao for proving Strichartz estimates to the stochastic setting and apply it to the wellposedness theory of stochastic dispersive equations, such as nonlinear Schrödinger and wave equations.

In investigating these problems, we aim to provide a unified approach to the various dispersive equations also considered in other projects of this proposal.

Publications

  1. , , and . Uniqueness of martingale solutions for the stochastic nonlinear Schrödinger equation on 3D compact manifolds. Stoch. PDE: Anal. Comp., 10(3):828–857, September . URL https://doi.org/10.1007/s40072-022-00238-w. [preprint] [bibtex]

  2. . The stochastic nonlinear Schrödinger equation in unbounded domains and non-compact manifolds. Nonlinear Differ. Equ. Appl., 27:40, July . URL https://doi.org/10.1007/s00030-020-00642-y. [preprint] [bibtex]

  3. , , and . Weak martingale solutions for the stochastic nonlinear Schrödinger equation driven by pure jump noise. Stoch. PDE: Anal. Comp., 8(1):1–53, March . URL https://doi.org/10.1007/s40072-019-00141-x. [preprint] [bibtex]

  4. , , and . Martingale solutions for the stochastic nonlinear Schrödinger equation in the energy space. Probab. Theory Related Fields, 174(3-4):1273–1338, August . URL https://doi.org/10.1007/s00440-018-0882-5. [preprint] [bibtex]

  5. . The nonlinear stochastic Schrödinger equation via stochastic Strichartz estimates. J. Evol. Equ., 18(3):1085–1114, September . URL https://doi.org/10.1007/s00028-018-0433-7. [preprint] [bibtex]

  6. and . Spectral multiplier theorems via $H^\infty$ calculus and $R$-bounds. Math. Z., 289(1-2):405–444, June . URL https://doi.org/10.1007/s00209-017-1957-1. [bibtex]

  7. , , , and . Analysis in Banach spaces. Vol. II, volume 67 of Ergebnisse der Mathematik und ihrer Grenzgebiete. 3. Folge. A Series of Modern Surveys in Mathematics [Results in Mathematics and Related Areas. 3rd Series. A Series of Modern Surveys in Mathematics]. Springer, Cham, December . Probabilistic methods and operator theory. [bibtex]

  8. and . New criteria for the $H^\infty$-calculus and the Stokes operator on bounded Lipschitz domains. J. Evol. Equ., 17(1):387–409, March . URL https://doi.org/10.1007/s00028-016-0360-4. [preprint] [bibtex]

  9. and . Paley–Littlewood decomposition for sectorial operators and interpolation spaces. Math. Nachr., 289(11-12):1488–1525, August . URL https://doi.org/10.1002/mana.201400223. [preprint] [bibtex]

Theses

  1. . Fractional order splitting for semilinear evolution equations. PhD thesis, Karlsruhe Institute of Technology (KIT), October . [bibtex]

  2. . Global solutions of the nonlinear Schrödinger equation with multiplicative noise. PhD thesis, Karlsruhe Institute of Technology (KIT), April . [bibtex]

Former staff
Name Title Function
Dr. Postdoctoral and doctoral researcher
apl. Prof. Dr. Principal investigator
Dr. Postdoctoral and doctoral researcher
Prof. Dr. Member