This course concentrates on theory, modeling, and simulation of light-matter interactions in extremely nonlinear regimes. The material is organized into a series of case studies, each consisting of a theoretical introduction, overview of models and corresponding numerical methods, computer-aided modeling practice sessions, and overview of open problems. Topics covered are selected to give the students a) the overview of modern nonlinear optics including its applications in strong-field science, b) hands-on experience with numerical modeling, and c) opportunity to gain skills needed to build light-matter interaction models applicable in various contexts. The course starts with an in-depth discussion of different approaches to numerical simulation of ultrashort-duration optical pulses. Next, third-order interactions in solids and gases, including Kerr effect, Raman effect and molecular orientation response are discussed with the emphasis on the numerical modeling and simulation practice. Second-order nonlinear interactions are covered with emphasis on solid-state media (crystals and polycrystalline). Section dealing with the strong-field physics concentrates on ionization in gaseous media, and includes a discussion of various approaches from quantum-level to phenomenological.
Instructor(s)
- kolesik