Dynamics of Doped Quantum Magnets

Superconductors are already used for MRI diagnostics, the particle accelerators at CERN, and the high-speed Maglev trains. However, most superconductors need to be cooled to about -270ºC by liquid helium, which is becoming increasingly scarce and expensive. High-temperature superconductors can potentially circumvent these obstacles. However, their fundamental properties remain a mystery, preventing us from developing more resilient and flexible materials. At the same time, doped quantum magnets is also an important example of strongly interacting quantum many-body systems out of equilibrium. In particular, the presence of holes in the lattice leads to the formation of quasi-particles called magnetic polarons that could well provide the effective charges carrying the super-current.

The research will be conducted at the Max Planck Institute Of Quantum Optics (MPQ) in Garching bei München, Germany. They are one of the world-leading institutions in quantum science, performing groundbreaking experiments with optical lattices and continuing to redefine the state of the art of cold-atom quantum simulations. At the same time, their Theory Division has pioneered many of the core concepts and applications of quantum computation, quantum simulation, and quantum many-body physics, that have become a foundation for modern quantum science and technology. The MPQ will, thus, be the ideal place to pursue the described project and greatly broaden my research scope.