Center for Computational Quantum Physics

CCQ’s mission is to develop the concepts, theories, algorithms and codes needed to solve the quantum many-body problem and to use the solutions to predict the behavior of materials and molecules of scientific and technological interest.

A new day is dawning for our ability to understand and control the behavior of materials and molecules, thanks to the combination of previously unimaginable theoretical concepts, improved computational capabilities and revolutionary developments in experimentation. Researchers at CCQ are developing the ideas, algorithms and codes that will take our understanding of the quantum mechanics of electrons in molecules and solids to a new level. CCQ is also an international focal point for computational materials science, hosting a lively array of meetings, workshops, conferences and visitor programs.

Research

Digital illustration of Quantum physics with hourglass cones and swirls

Dynamics and Control At the Center for Computational Quantum Physics, we are developing the conceptual basis, theoretical formalism and computational tools needed to use the quantum nature of light to understand and control quantum phenomena in complex systems. Read More

Colorful digital illustration of quantum materials

Quantum Materials What arrangement produces a material with an optimal thermoelectric figure of merit, or a combination of magnetic and ferroelectric properties, or a high superconducting critical temperature? Read More

Illustration that shows the lattice structure of anatase titanium dioxide along with a graphic representation (purple) of a 2-D exciton — an electron-hole pair — generated by the absorption of light

Software Libraries A major effort of the CCQ is the development and support of high quality open-source software for quantum many-body physics research. Making software which is reliable, efficient, and productive accelerates discovery and fosters scientific consensus and reproducibility. Read More

Digital illustration of quantum many-body problem

Theory and Methods The quantum many-body problem is one of the hard problems of complexity theory: A direct solution requires computational resources that grow exponentially with the size of the problem to be solved. Read More

Collaborative Work

Optical cavity between two mirrors showing vacuum fluctuations of light (yellow wave)

Max Planck-New York Center for Nonequilibrium Quantum Phenomena

Columbia University, the Flatiron Institute in New York City and the Max Planck Society in Germany have created a partnership, called the Center for Nonequilibrium Quantum Phenomena.

CCQ
| Columbia University
| Max Planck Institute for the Structure and Dynamics of Matter in Hamburg (MPSD)
| Max Planck Institute for Polymer Research in Mainz (MPIP)

News & Announcements

September 16, 2025

Flatiron Institute Scientists Valentin Crépel and Ore Gottlieb Named Blavatnik Regional Award Honorees By Jane Beaufore

June 17, 2025

Physicists Cool Quantum Simulator to Record-Breaking Low Temperatures

May 14, 2025

Quantum Physicists Tune Material’s Property Using Energy of ‘Empty’ Space By Thomas Sumner

Upcoming Events

No events are scheduled in October.

Andreas Gleis: Intrinsic Strange Metal due to Heavy-Fermion Quantum Criticality

September 29, 2025
DMFT-QE Symposium: September 29th

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Andreas Gleis: Intrinsic Strange Metal due to Heavy-Fermion Quantum Criticality September 29, 2025 |
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Cyrus Dreyer: Fermi-Liquid T2 Resistivity: Dynamical Mean-Field Theory Meets Experiment

September 29, 2025
DMFT-QE Symposium: September 29th

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Cyrus Dreyer: Fermi-Liquid T2 Resistivity: Dynamical Mean-Field Theory Meets Experiment September 29, 2025 |
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Fabian Kugler: Finite-difference parquet method and the strong-coupling pseudogap

July 7, 2025
DMFT-QE Symposium: July 7th

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Fabian Kugler: Finite-difference parquet method and the strong-coupling pseudogap July 7, 2025 |
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Anna Kauch: Two-site entanglement in the two-dimensional Hubbard model from parquet dynamical vertex approximation

July 7, 2025
DMFT-QE Symposium: July 7th

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Anna Kauch: Two-site entanglement in the two-dimensional Hubbard model from parquet dynamical vertex approximation July 7, 2025 |
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Leadership

Antoine Georges, Ph.D.

Director, CCQ

Antoine Georges is a professor of physics at the Collège de France, where he holds the chair in condensed matter physics. He also has joint appointments with École Polytechnique and the University of Geneva. He received his Ph.D. from the École Normale Supérieure in 1988.…

Andrew Millis, Ph.D.

Co-Director, CCQ

Andrew Millis is co-director of the Center for Computational Quantum Physics at the Flatiron Institute and professor of physics at Columbia University. He currently serves as Managing Director of the Flatiron Institute.

Center for Computational Quantum Physics

Research

Collaborative Work

News & Announcements

Upcoming Events

Event Videos

Andreas Gleis: Intrinsic Strange Metal due to Heavy-Fermion Quantum Criticality

Cyrus Dreyer: Fermi-Liquid T2 Resistivity: Dynamical Mean-Field Theory Meets Experiment

Fabian Kugler: Finite-difference parquet method and the strong-coupling pseudogap

Anna Kauch: Two-site entanglement in the two-dimensional Hubbard model from parquet dynamical vertex approximation

Leadership

Antoine Georges, Ph.D.

Andrew Millis, Ph.D.

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