Our understanding of physics evolves hand in hand with advances in our ability to measure and control the properties of light and matter. Well-isolated atoms and molecules have long served as one of the best-controlled systems for studying and answering fundamental questions in physics. The latest developments in metrology, including optical clocks accurate to 18 digits and matter-wave interferometers that split atomic wave packets by several decimetres, are striking demonstrations of the mastery that has been achieved over single-particle quantum dynamics. Many-body systems, in which interactions and quantum correlations between particles play an essential role, exhibit even richer quantum features. Within this CRC, we will extend the control already exerted over single-particle systems to large interacting and entangled quantum systems and develop applications of such systems in metrology. For this purpose, experts from many-body physics, quantum information, quantum gases, and metrology will work together to develop novel methods for generating, manipulating, and detecting quantum states of matter. The investigation of these states will allow us to gain a deeper understanding of the quantum properties of many-body systems, one of the great challenges in modern physics. At the same time, mastery of many-body effects combined with novel state preparation and interrogation protocols and the design of composite quantum systems, promises significantly enhanced performance for quantum sensors. High-precision measurements with such next generation optical clocks and matter-wave interferometers will open up new regimes for tests of fundamental physics. We will address questions concerning a possible change in fundamental constants, searches for dark matter candidates, a violation of fundamental symmetries in physics, and the coupling of quantum systems to gravity. With these investigations, we make an important contribution to the understanding of the foundations of physics.

DFG Programme Collaborative Research Centres

• A01 - Trapped-ion quantum magnetism (Project Heads Ospelkaus, Christian ;  Torkzaban, Celeste )
• A03 - Detecting and engineering nonclassical quantum many-body states of polar molecules (Project Heads Karpa, Leon ;  Ospelkaus, Silke ;  Zenesini, Ph.D., Alessandro )
• A04 - Controlling polar molecules in optical lattices (Project Heads Ospelkaus, Silke ;  Santos, Luis ;  Weimer, Hendrik )
• A05 - Theory of LMT atom interferometers involving gravitational fields (Project Heads Gaaloul, Naceur ;  Giulini, Domenico ;  Hammerer, Klemens )
• A07 - Dynamics of ion Coulomb crystals (Project Heads Mehlstäubler, Tanja E. ;  Santos, Luis ;  Weimer, Hendrik )
• A08 - Dipolar few-body systems of ultracold CaF molecules (Project Heads Ospelkaus, Silke ;  Siercke, Mirco )
• A09 - Frequency metrology and precision spectroscopy with designed states and measurements (Project Head Hammerer, Klemens )
• A10 - Quantum error correction for metrology (Project Heads Osborne, Tobias J. ;  Raussendorf, Ph.D., Robert )
• B01 - Entangled neutral atoms for interferometry beyond the standard quantum limit (Project Heads Ertmer, Wolfgang ;  Klempt, Carsten ;  Santos, Luis )
• B02 - Optical clocks testing fundamental physics (Project Heads Huntemann, Nils ;  Lisdat, Christian ;  Sterr, Uwe )
• B03 - Multi-ion spectroscopy for optical clocks (Project Heads Jordan, Elena ;  Mehlstäubler, Tanja E. ;  Schmidt, Piet Oliver )
• B04 - Coherent excitation of a nucleus (Project Head Peik, Ekkehard )
• B06 - Quantum metrology with trapped (anti-)protons (Project Heads Cornejo, Juan Manuel ;  Ospelkaus, Christian )
• B07 - Macroscopically delocalised quantum states of matter (Project Heads Ertmer, Wolfgang ;  Rasel, Ernst Maria ;  Schlippert, Dennis )
• B09 - Quantum clock interferometry (Project Heads Schlippert, Dennis ;  Schubert, Christian )
• B10 - The quantum limits of sensing for ultralight dark matter detection (Project Heads Fuchs, Elina ;  Hammerer, Klemens ;  Osborne, Tobias J. )
• Z - Central Tasks (Project Head Schmidt, Piet Oliver )

• A02 - Entanglement in momentum space (Project Heads Ertmer, Wolfgang ;  Klempt, Carsten ;  Santos, Luis )
• A06 - Representation of quantum correlations in complex systems (Project Heads Hammerer, Klemens ;  Osborne, Tobias J. ;  Werner, Reinhard F. )
• B05 - Quantum engineering molecular ions for precision spectroscopy (Project Head Schmidt, Piet Oliver )
• B08 - Quantum dynamics under gravitation (Project Heads Giulini, Domenico ;  Lämmerzahl, Claus )
• Ö - The out-of-school laboratoy foeXlab: Science education – science communicaton – science (Project Heads Rasel, Ernst Maria ;  Schmidt, Piet Oliver ;  Weßnigk, Susanne )

Applicant Institution Gottfried Wilhelm Leibniz Universität Hannover

Participating Institution Deutsches Zentrum für Luft- und Raumfahrt (DLR)
Institut für Satellitengeodäsie und Inertialsensorik; Physikalisch-Technische Bundesanstalt (PTB)

Spokesperson Professor Dr. Piet Oliver Schmidt