Funding

ERC Starting Grant: mlQuDyn

A key scope of quantum many-body theory is the identification of universal behavior in quantum matter, where macroscopic properties become independent of microscopic details. In recent years the quest for phases with novel universal properties has seen a particular push by forcing systems out of equilibrium, which has opened up new dynamical paradigms. These developments not only hold the promise to theoretically uncover unrecognized universal dynamical behavior, but are also driven by the enormous advances in quantum simulators such as ultra-cold atoms, which have nowadays achieved unique capabilities in generating and probing such nonequilibrium quantum states. Still, their theoretical description is facing severe challenges. It is the aim of this proposal to advance the theoretical understanding and predictive power of quantum many-body theory by a crossdisciplinary approach at the interface between quantum dynamics and machine learning.

DFG-Transregio-Sonderforschungsbereich TRR 360

Using carefully chosen constraints – intrinsic rather than purely geometrical – we prepare and investigate 3D materials that host novel quantum states. Our research concentrates on the manifestations of constraints in solid-state materials and the practical implementation of these constraints as the way to control quantum states and eventually tailor them to new functionalities. TRR360 Homepage

 

A5: Optical conductivities and entanglement in magnetic topological semimetals (Chioncel, Heyl)
B6: Dynamics of correlated quantum magnets (Knolle, Pollmann, Heyl)
C4: Ultrastrong matter-magnon coupling phenomena (Deisenhofer, Kollar)

 

ARC Discovery Project

Pushing the digital limits in quantum simulation for advanced manufacturing

DFG-Transregio-Sonderforschungsbereich TRR 80 (01/2010 - 06/2022)

The collaborative research center TRR 80 connects fundamental research on emergent new materials properties driven by strong electronic correlations with the focussed exploration for possible new functionalities in technological devices. At the heart of the materials properties of interest are the strong interplay of charge, spin, orbital, and lattice degrees of freedom, leading to a multitude of complex new phases on different length and time-scales with fascinating electronic properties as well as novel generic excitations. Systematic determination of large susceptibilities to applied fields, perturbations and defects yield complex phase diagrams, which represent a major avenue towards tailored functionalities that may be exploited in designed composite-systems.

 

E2: Determination of Electronic Structure Using Spin-Polarized Positrons (Hugenschmidt, Böni, Chioncel)
E5: Cooperative Phenomena in Correlated Materials and Topological Properties (Kampf, Kopp)
F6: Electronic Correlations in Models and Materials (Chioncel, Kollar)
G7: Electronic Structure and Transport Properties of Correlated Inhomogeneous Systems (Chioncel, Eckern)
MGK: Integrated Research Training Group / Integrated Graduate School (Pfleiderer, Kollar, Benckiser)

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