Abstract:
In particular, in the talk we will see that (i) for some Schrödinger equations the minimum control time for global L^2-approximate controllability is zero, independently of the initial state of the system, and (ii) for some wave equations the minimum control time for global H^1 x L^2-approximate controllability coincides with the maximum radius of a ball contained in the zero set of the initial state.
The strategy to prove (i) consists in decoupling the control of the Schrödinger equation into the control of two equations: a Hamilton-Jacobi equation for the angular phase, and a Liouville transport equation for the radial density, associated to the wavefunction. Our contribution is the control of the radial density thanks to a link with the control of the group of diffeomorphisms of the underlying torus or Euclidean space. Such a link is a consequence of a celebrated theorem of Jürgen Moser.
The talk will be based on the article [1] and the preprint [2] in collaboration with Karine Beauchard and Thomas Perrin (École Normale Supérieure de Rennes, France).
[1] Karine Beauchard, Eugenio Pozzoli; Small-time approximate controllability of bilinear Schrödinger equations and diffeomorphisms. Ann. Inst. Henri Poincaré C Anal. Non Linéaire (2025), published online first.
[2] Karine Beauchard, Thomas Perrin, Eugenio Pozzoli; Approximate controllability of a bilinear wave equation and minimum time. (2026) Preprint arXiv 2601.19544
Biography:
Eugenio Pozzoli has been an associate researcher (chargé de recherche) at CNRS, Institut de Recherche Mathématique de Rennes, France, since 2023. He obtained a Ph.D. in 2021 at Sorbonne University, Paris, France, under the supervision of U. Boscain and M. Sigalotti. His research interests include the control of partial differential equations and diffeomorphisms groups, with applications in quantum mechanics and deep learning.
Seminar by the NYU-ECNU Institute of Mathematical Sciences at NYU Shanghai
This event is open to the NYU Shanghai community and Math community.