Whether and how a system equilibrates towards some sort of steady long-time limit is a key issue in many areas of modern many-body physics. While this question has a long and fertile history, it has experienced an upsurge of interest in recent years due to the advent of novel materials and cold atomic gases as well as due to the discovery of new states of matter such as topological states and many-body localized phases. In particular, the theoretical understanding of such fundamental equilibration and thermalization issues has seen substantial progress by the emerging concepts of eigenstate thermalization and typicality of pure quantum states, and by the invention of powerful numerical methods. Even much less is known about the route to equilibrium itself, and the rigorous derivation of thermodynamic relaxation from truly microscopic principles is still a major challenge to theory. The objective of our herewith proposed Research Unit (\Forschergruppe") is to tackle these theoretical challenges by studying the principles of relaxation processes at the microscopic level. At the center of our investigation are generic and complex systems under non-equilibrium conditions induced by highly non-thermal initial states or by strong external driving forces. We particularly aim at unveiling the role of the speci_c initial-state realization in isolated as well as open scenarios with explicit coupling to a bath. Key issues include the emergence of conventional exponential relaxation, phenomenological transport laws, Gibbsian equilibrium, and fundamental theorems on the work performed. While our research projects focus on clarifying these theoretical issues, the models considered are also intimately related to materials realized in nature such as magnetic molecules, low-dimensional quantum magnets, and topological at-band systems. The complexity of such models requires state-of-the-art analytical and numerical methods equally distributed over the institutions involved.

DFG Programme Research Units

• Approach to equilibrium in interacting flat band systems (Applicant Dahm, Thomas )
• Combinations of damped harmonic oscillations as stable building blocks of autocorrelation functions in quantum many-body systems (Applicants Gemmer, Jochen ;  Michielsen, Kristel )
• Coordination Funds (Applicant Steinigeweg, Robin )
• Decoherence and Relaxation in Quantum Spin Clusters (Applicants Michielsen, Kristel ;  Schnack, Jürgen )
• Emergence of nonequilibrium steady states in periodically driven closed composite quantum systems (Applicant Holthaus, Martin )
• Nonequilibrium dynamics in 2D clusters from the perspective of quantum typicality and eigenstate thermalization (Applicants Michielsen, Kristel ;  Steinigeweg, Robin )
• Nonequilibrium transport and thermodynamics in driven lattice gases (Applicant Maass, Philipp )
• Typical and Non-typical Temporal Relaxation Processes in Macroscopic Quantum Systems (Applicant Reimann, Peter )
• Work statistics in classical and quantum driven billiards (Applicant Engel, Andreas )

Spokesperson Professor Dr. Robin Steinigeweg