Quantum physics and general relativity are probably the most successful and well-tested theories of modern science. At the same time, their fundamental concepts are so dramatically different that there is even disagreement on the most obvious questions such as “how does a mass in a quantum superposition state gravitate?“. Achieving progress on such foundational questions requires experiments at the interface between quantum physics and gravity, of which to date only a few of exist. The main objective of QLev4G is to establish quantum control of levitated massive objects as a new paradigm system for such experiments and to enter a hitherto inaccessible parameter regime of large mass and long quantum coherence. This includes the development of methods and technologies that are necessary for realizing such quantum states of matter.
The project is built on the enormous recent success in quantum control of the motion of solid-state mechanical resonators, which has emerged over the last decade as a new branch of interdisciplinary research in quantum and solid-state physics. In conclusion, QLev4G has successfully transferred this methodology to optically and magnetically levitated systems to achieve (i) exceptional sensitivity to weak gravitational forces, hence enabling measurements of gravity between sub-millimeter objects; (ii) unprecedented levels of decoupling from the environment, thereby opening up a new route for long-lived quantum coherence of genuinely massive systems.