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The objective of this course is to cover the background required to understand one major system in future quantumbased technologies in the solid state, namely localized spins of atoms embedded in a solid state matrix.
The main goal of this course is to provide an advanced view of the optical response of quantum materials.
Modern physics is characterized by an increasing complexity of systems under investigation, in domains as diverse as condensed matter, astrophysics, biophysics, etc. Due to the growing availability of experimental data, data-driven modelling is emerging as a powerful way to model those systems. The objective of the course is to provide the theoretical concepts and practical tools necessary to understand and to use these approaches.
Mixed theoretical/experimental class covering light-matter interaction in condensed matter systems and applications to advanced photonic and opto-electronic devices including for quantum technologies.
Mini-experimental projects (3x4h) in research labs
Recent years have seen enormous experimental progress in preparing, controlling and probing quantum systems in various regimes far from thermal equilibrium. Examples include systems as ultra-cold atomic quantum gases under time-dependent perturbations, driven non-linear cavity QED systems or strongly correlated electrons in solid-state materials under ultra-fast optical excitations.
This course covers advanced topics in Statistical Physics. It assumes a very good knowledge of the Statistical Physics concepts and methods taught in standard lectures at the M1 level.
Students performing a library-based project are expected to study a series of original research articles around a common subject, under the supervision of a senior researcher.
La théorie de la Relativité Générale est une modélisation des liens entre matière et gravitation à travers des équations reliant des objets géométriques.