- Trainer/in: Simone Fodera
- Trainer/in: Ming Huang
- Trainer/in: Oleksandra Kovalska
- Trainer/in: Marc Ritter
- Trainer/in: Honghao Tu
- Trainer/in: Jan von Delft
- Trainer/in: Changkai Zhang
In this course, different strategies for
manipulating light-matter interaction in nanoscale are presented and discussed.
Special attention is given to the basics and applications of plasmonics,
optical microcavities, nanophotonic biosensing, chiral nanophotonics,
quasi-Bound States in the Continuum based- and active metasurfaces, nanophotonics
in the quantum regime/single quantum emitters and thermometry in nanoscale.
- Trainer/in: Leonardo de Souza Menezes
- Trainer/in: Thomas Possmayer
- Trainer/in: Andreas Tittl
This class builds upon the “E_M1 Advanced Solid
State Physics” lecture and develops an introductory-level insight into the main
concepts and the rich phenomenology of graphene and other two-dimensional
materials, leading up to the recent advancements in moiré superlattices. In
particular, the class aims to introduce all the main concepts and techniques
that are needed for the study of the key experimental literature on the
emergent field of moiré materials, with a strong bias towards low-temperature
electronic experiments.
- Trainer/in: Dmitri Efetov
- Trainer/in: Quinten Akkerman
- Trainer/in: Emiliano Cortés
- Trainer/in: Franz Gröbmeyer
- Trainer/in: Alena Khmelinskaia
- Trainer/in: Alexander Urban
- Trainer/in: Bert Nickel
- Trainer/in: Alexander Urban
Few-body physics in ultracold gases (Feshbach
resonances, Efimov effect, Rydberg physics, Polaritons), Problems with baths
(Bose and Fermi polarons, Fröhlich model, Quantum impurities), Few-body physics
in strongly correlated systems (Doped antiferromagnets, Spin-charge separation,
emergent gauge theories)
- Trainer/in: Pit Bermes
- Trainer/in: Fabian Bohrdt
- Trainer/in: Alberto Cavallar
This course will cover two main pillars of modern
quantum many-body physics: (i) quantum many-body dynamics and (ii) quantum
simulation. We will cover nonthermal far-from-equilibrium many-body dynamics
such as quantum many-body scarring, many-body localization, and Hilbert-space
fragmentation. A big focus will be on various target quantum many-body systems,
in particular lattice gauge theories, whose local conservation laws give rise
to many of these phenomena. We will go over schemes to reliably realize these
models onto state-of-the-art quantum-hardware platforms from cold atoms to
trapped ions and superconducting qubits. The course will include homework
assignments as well as coding projects where students will learn numerical
methods such as exact diagonalization. At the end of the course, students'
knowledge will be at the forefront of quantum simulation and
far-from-equilibrium quantum many-body dynamics, and be able to pursue research
in these fields.
- Trainer/in: Jad Halimeh
- Trainer/in: Lode Pollet
- Trainer/in: Lechen Xu