This collaboration, originally established between Columbia University, the Flatiron Institute, and two Max Planck Institutes in Germany, will now include Cornell University. The centre’s expansion aims to deepen research into the unique properties of quantum materials, which hold significant potential for advancements in technologies such as quantum computing, sensors, and networks.
Pushing the boundaries of quantum materials
At the heart of the centre’s work is the exploration of non-equilibrium quantum phenomena, which occur when materials are pushed beyond their normal, stable states.
These phenomena can lead to the emergence of entirely new properties, such as unique forms of superconductivity and magnetism.
By understanding and controlling these properties, researchers hope to unlock innovative applications for quantum technologies.
“This renewal will allow our team to continue our innovative work combining modern experimental physics methods with breakthroughs in materials synthesis, nonlinear optical and electronic spectroscopies, and cutting-edge theoretical, computational, and data science methods to provide an unprecedented understanding of quantum matter at the shortest lengths and time scales,” said Andrew Millis, Director of the Center and professor of physics at Columbia University.
“The collaborations enabled by the centre will solidify the positions of the participating institutions as world leaders in one of the most vibrant and exciting areas of current research in the physical sciences.”
New capabilities and directions for quantum research
The inclusion of Cornell University adds new capabilities to the centre’s research portfolio, particularly in the areas of material synthesis and quantum measurement.
Additionally, the Max Planck Institute’s new Microstructured Quantum Matter Department will contribute to the design and creation of novel quantum materials.
This enhanced expertise will allow the centre to push research into innovative areas, such as using light to manipulate material properties and bridging the gap between atomic, molecular, and optical physics with quantum materials.
Groundbreaking achievements and future goals
The centre has already achieved pioneering work, including the development of ultrafast optical scanning tools and the discovery of new physical properties in quantum materials.
Looking ahead, researchers aim to further their understanding of light-matter interactions and design materials with dynamic control capabilities.
The renewed collaboration promises exciting new advances in quantum materials, driving innovation and discovery in one of the most promising fields of modern science.
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