AtomQT is dedicated to propelling Europe to the forefront of the Second Quantum Revolution. The mission of AtomQT is to establish an extensive network of expert groups specializing in cold-atom quantum physics. This network will serve as a catalyst, accelerating the swift development and commercialization of quantum technology grounded in

The past decades have witnessed the development of a vivid scientific community around the topics of quantum technologies. One essential direction of research concerns the quest for robust quantum systems, which can preserve and optimally harness quantum coherence to perform operations unthinkable through the methods of classical physics. In particular,

The transport properties of many strongly correlated materials are governed by interactions between localised spins and mobile fermions. Even a single localised spin impurity can have a profound impact on the motion of numerous fermions in its proximity, giving rise to a notable phenomenon in quantum many-body physics known as

MAWI is a European Doctoral Network under the Marie Sklodowska-Curie Action, currently in the phase of recruiting PhD students interested in the topics of ultra-cold atoms, matter waves, quantum sensing, and atomtronics. The objective of the MAWI project is to train young researchers in the emerging fields of matter-wave interferometry

The primary goal of QuCoM is to demonstrate the proof of concept (TRL 1) for a levitated acceleration sensor capable of detecting gravity in the quantum-controlled regime, especially for small masses. To achieve this objective, we aim to explore the interplay between quantum mechanics and gravity within a parameter range

The 20th century bequeathed a scientific and technological legacy marked by milestones like quantum mechanics and groundbreaking space missions. Both pursuits have paved new paths for expanding our understanding of nature, standing as true benchmarks of modern science. Quantum theory and space science constitute foundational elements of a robust research

Microscopic systems can assume quantum configurations devoid of classical counterparts. However, as we transition toward the macroscopic domain, the potential for such non-classical behavior diminishes, leaving us with no evidence of quantum phenomena at larger scales. Why does this happen, and how does quantumness dissipate as we move beyond the

The goal of the QuFree project is to establish a free-space communication link, meaning communication through the air, for the secure exchange of keys generated with quantum technology. Air serves as the medium for transmitting quantum communication complementary to optical fiber. Therefore, QuFree complements the Quantum FVG project, already funded