'NEUQUAM' research group
Welcome to the JGU Mainz research group on non-equilibrium universality in quantum matter ('NEUQUAM')
Welcome to the JGU Mainz research group on non-equilibrium universality in quantum matter ('NEUQUAM')
Our team explores emergent behaviour in driven-dissipative systems from an interdisciplinary angle, combining condensed matter, AMO and quantum information. The common focus is on systems where strong inter-particle correlations are a necessary ingredient to capture dynamics and/or to shape phases of matter which could not be described in terms of single particle physics, or through the dynamcs of collective degrees of freedom.
Our team explores emergent behaviour in driven-dissipative systems from an interdisciplinary angle, combining condensed matter, AMO and quantum information. The common focus is on systems where strong inter-particle correlations are a necessary ingredient to capture dynamics and/or to shape phases of matter which could not be described in terms of single particle physics, or through the dynamcs of collective degrees of freedom.
Our work is embedded in a dense network of local and international research centers revolving around the Johannes Gutenberg University (JGU) of Mainz. Our main collaborations are located in the US, Switzerland, Spain and Germany.
Our work is embedded in a dense network of local and international research centers revolving around the Johannes Gutenberg University (JGU) of Mainz. Our main collaborations are located in the US, Switzerland, Spain and Germany.
We rank teamwork and dedication as our highest values.
We rank teamwork and dedication as our highest values.
We are supported by the DFG through the project 'HADE-QUAM'
We are supported by the DFG through the project 'HADE-QUAM'
We are supported by the EU through the project 'QuSiED'
We are supported by the EU through the project 'QuSiED'
The high performance cluster Mogon II at JGU hosts our large scale simulations for quantum many-body dynamics
The high performance cluster Mogon II at JGU hosts our large scale simulations for quantum many-body dynamics