Cooperative behavior can be understood as the enhanced response of a system of many particles with respect to isolated entities. This collective response is brought about by some mutual coupling among the entities establishing non-local and long-range correlations in space and time. In the classical world it characterizes, for instance, the dynamics of flocking birds, the swarm intelligence of fish, or the development of trends in human societies. In the quantum world, a prominent example for cooperative behavior is superradiance, where quantum interference modifies the response of an ensemble of emitters to radiation in a fundamentally different manner from the scattering properties of individual particles. This modification sets in via entanglement among the emitters induced, e.g., by the observation of outgoing photons or by controlling and tailoring their mutual interactions. Quantum cooperative behavior is present at various length and energy scales, from the subatomic to the macroscopic world, from hard x-rays to visible light down to molecular vibrations, and shows up in a vast multitude of platforms. The experimental control as well as the theoretical description is challenging, especially if noise, disorder and fluctuations are taken into account. The development of a general framework for quantum cooperativity is an open problem in physics.This mindset is the starting point of the research efforts in the CRC-TR Quantum Cooperativity of Light and Matter - QuCoLiMa. Our objective is to characterize, control and eventually utilize cooperativity at the quantum level and to understand the interplay of quantum interference and entanglement in the collective response of many-body quantum systems interacting with light. In particular, the role of the quantum properties of radiation will be explored in establishing and mediating quantum cooperative phenomena in a variety of complex matter systems. This will be accomplished either in a bottom-up approach, where the quantum cooperative behavior is analyzed as the particle number is scaled up in a controlled manner from the microscopic to the mesoscopic regime, or top-down, where in a system with a macroscopic size quantum cooperative behavior of collective degrees of freedom is identified and controlled. To this end, the QuCoLiMa brings together leading theorists and experimentalists with cutting-edge expertise in quantum optics and condensed-matter physics. The successful implementation of this research programme will lead to a systematic understanding of the buildup of spatio-temporal quantum correlations in mesoscopic light-matter systems and identify the key ingredients for exploiting robust quantum dynamics for quantum technological applications such as enhanced sensing, secure communication, and quantum computing.

DFG Programme CRC/Transregios

International Connection Austria

• A01 - Cooperative light emission and spatio-temporal photon correlations from trapped ion arrays (Project Heads Schmidt-Kaler, Ferdinand ;  von Zanthier, Joachim )
• A02 - Generation of photonic cluster states from color center-cavity system (Project Head Becher, Christoph )
• A03 - Correlated x-ray photons for incoherent diffraction imaging (Project Heads Röhlsberger, Ralf ;  von Zanthier, Joachim )
• A04 - Spatio-temporal correlations of electrons emitted from femtosecond laser-driven needle sources (Project Head Hommelhoff, Peter )
• A05 - Cooperative effects of a defined number of organic molecules embedded in a dielectric antenna (Project Head Götzinger, Stephan )
• A06 - Tailor-made beyond-one-excitation quantum states for quantum information and communication (Project Head van Loock, Ph.D., Peter )
• B01 - Collective quantum dynamics of structural- and spin-defects in ion crystals (Project Heads Morigi, Giovanna ;  Schmidt-Kaler, Ferdinand )
• B02 - Levitated ferrimagnetic particles in hollow-core photonic crystal fibres (Project Heads Joly, Nicolas ;  Russell, Philip St. J. )
• B03 - Point defects in silicon carbide: Towards a platform for the coupling of light, spin and Mechanics (Project Heads Bockstedte, Michel ;  Neu-Ruffing, Elke ;  Weber, Heiko B. )
• B04 - Opto-mechanical lasing mechanisms in cold atoms (Project Head Eschner, Jürgen )
• B05 - Optomagnomechanical arrays (Project Head Viola Kusminskiy, Silvia )
• C01 - One-dimensional photon-mediated cooperativity of quantum emitters (Project Head Sandoghdar, Ph.D., Vahid )
• C02 - Light-induced correlations in dense atomic media (Project Heads Schmidt, Kai Phillip ;  Windpassinger, Patrick )
• C03 - Mechanical and chemical control of single and multiphoton emission (Project Heads Basché, Thomas ;  Jung, Gregor )
• C04 - X-ray photonic structures for control of cooperative emission from resonant nuclei (Project Heads Palffy-Buß, Adriana ;  Röhlsberger, Ralf ;  von Zanthier, Joachim )
• C05 - Quantum cooperative helical metafilms for producing nonclassical light (Project Heads Chekhova, Ph.D., Maria ;  Krstic, Vojislav )
• D01 - Cooperative effects in coupled quantum emitter systems (Project Head Genes, Ph.D., Claudiu )
• D02 - Spatio-temporal structures in interacting spin systems (Project Head Morigi, Giovanna )
• D03 - Competing interactions in strongly correlated light-matter assemblies (Project Head Schmidt, Kai Phillip )
• D04 - Synchronizing quantum spins with long-range dissipation (Project Head Marino, Jamir )
• D05 - Quantum Cooperativity and Synchronization (Project Head Marquardt, Florian Kai )
• D06 - Entangling collective behavior of quantum materials and quantum light (Project Head Eckstein, Martin )
• MGK - Integrated Research Training Group (Project Head Schmidt, Kai Phillip )
• Z02 - Quantum simulation methods for cooperative effects in strongly correlated light-matter systems (Project Heads Hartmann, Michael J. ;  Wilhelm-Mauch, Frank K. )
• ZZ01 - Central Tasks of the Collaborative Research Centre (Project Head von Zanthier, Joachim )

Applicant Institution Friedrich-Alexander-Universität Erlangen-Nürnberg

Co-Applicant Institution Johannes Gutenberg-Universität Mainz; Universität des Saarlandes

Participating Institution Deutsches Elektronen-Synchrotron (DESY); Friedrich-Schiller-Universität Jena
Institut für Optik und Quantenelektronik; Johannes Kepler Universität Linz
Institute for Theoretical Physics; Max-Planck-Institut für die Physik des Lichts

Participating University Rheinland-Pfälzische Technische Universität Kaiserslautern-Landau
Fachbereich Physik
Arbeitsgruppe Physik und Technologie der Nanostrukturen

Spokesperson Professor Dr. Joachim von Zanthier