Group “Classical and Quantum Dynamical Systems”
The main research focus of the Quantum Dynamics and Spectral Analysis team is the mathematical study of problems arising in physics and their applications. Most of our activity concerns the spectral and scattering properties of models of nanostructures, models in atomic physics and particle physics in quantum field theory, the properties of solutions of the PDEs of physics, and the properties of uniqueness, stability, and reconstruction in inverse problems.
The main strengths of our scientific activity:
Nanostructures: Propagation properties of waves in optical fibers and quantum waveguides; spectral properties of differential operators on graphs; study of the semiconducting character and gap opening in graphene samples with periodic perforations.
PDEs and inverse problems: Convergence-to-equilibrium properties for dilute particle gases and regularization of solutions to the nonlinear Kac and Boltzmann equations; inverse problems in models of anomalous diffusion involving fractional-time equations (complex fluids, porous media, diffusion of pollutants in soil); inverse problems for characteristic coefficients (diffusion, absorption, etc.), with applications to waveguides, angiogenesis, Black–Scholes models, etc.
Standard Model, QFT and atomic physics: Rigorous analysis of Hamiltonians in particle physics: non-perturbative quantum electrodynamics; spectral theory for weak interaction models and muonic atoms; derivation of the Van der Waals–London laws; spectral theory in quantum field theory on de Sitter spaces and scattering theory on Lorentzian manifolds in QED; edge currents and surface states for magnetic Schrödinger operators.
| ALVAREZ | Benjamin | Research teacher | +33.4.91.26.97.92 | Contact |
| BARBAROUX | Jean-Marie | Research teacher Team leader « Quantum Dynamics and Spectral Analysis » | +33.4.91.26.95.03 | Contact |
| BRIET | Philippe | Research teacher | +33.4.91.26.95.11 | Contact |
| GOUTTENEGRE | Hugo | Ph.D. | Contact | |
| PANATI | Annalisa | Research teacher | +33.4.91.26.95.46 | Contact |
| PILLET | Claude-Alain | Research teacher | +33.4.91.26.95.32 | Contact |
| ROULEUX | Michel | Research teacher | +33.4.91.26.97.97 | Contact |
| SOCCORSI | Eric | Research teacher | +33.4.91.26.95.37 | Contact |
Magnetic Dirac systems: Violation of bulk-edge correspondence in the zigzag limit
Letters in Mathematical Physics, 2024, 114 (4), pp.93. (10.1007/s11005-024-01839-3)
Multidimensional Borg–Levinson uniqueness and stability results for the Robin Laplacian with unbounded potential
Documenta Mathematica, 2024, 29 (4), pp.959-984. (10.4171/DM/964)
A note on two-times measurement entropy production and modular theory
Letters in Mathematical Physics, 2024, 114 (1), pp.32. (10.1007/s11005-024-01777-0)
On the thermodynamic limit of two-times measurement entropy production
Reviews in Mathematical Physics, 2024, (10.1142/S0129055X24610063)
Identification of unbounded electric potentials through asymptotic boundary spectral data
Research in the Mathematical Sciences , 2023, 11 (1), pp.4. (10.1007/s40687-023-00417-8)
Logarithmic stable recovery of the source and the initial state of time fractional diffusion equations
SIAM Journal on Mathematical Analysis, 2023, 55 (4), pp.3888-3902. (10.1137/22M1504743)
Solving time-fractional diffusion equations with a singular source term
Inverse Problems, 2023, 39 (12), pp.125005. (10.1088/1361-6420/ad0176)
Stable recovery of noncompactly supported electromagnetic potentials in unbounded domain
2023
Determination of source or initial values for acoustic equations with a time-fractional attenuation
Analysis and Applications, 2023, 21 (05), pp.1105-1130. (10.1142/S0219530523500100)
Inverse Problems for Subdiffusion from Observation at an Unknown Terminal Time
SIAM Journal on Applied Mathematics, 2023, 83 (4), pp.1496-1517. (10.1137/22M1529105)
