Observation and stabilization of photonic Fock states in a hot radio-frequency resonator
Mario F. Gely (Kavli institute of nanoscience Delft, TU Delft - Applied Sciences)
Marios Kounalakis (TU Delft - Applied Sciences, Kavli institute of nanoscience Delft)
Christian Dickel (Kavli institute of nanoscience Delft, TU Delft - QCD/DiCarlo Lab)
Jacob Dalle (Kavli institute of nanoscience Delft, TU Delft - Applied Sciences)
Rémy Vatré (TU Delft - Applied Sciences, Kavli institute of nanoscience Delft)
Brian Baker (Northwestern University)
Mark D. Jenkins (Kavli institute of nanoscience Delft, TU Delft - Applied Sciences)
Gary A. Steele (TU Delft - Applied Sciences, Kavli institute of nanoscience Delft)
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Abstract
Detecting weak radio-frequency electromagnetic fields plays a crucial role in a wide range of fields, from radio astronomy to nuclear magnetic resonance imaging. In quantum optics, the ultimate limit of a weak field is a single photon. Detecting and manipulating single photons at megahertz frequencies presents a challenge because, even at cryogenic temperatures, thermal fluctuations are appreciable. Using a gigahertz superconducting qubit, we observed the quantization of a megahertz radio-frequency resonator, cooled it to the ground state, and stabilized Fock states. Releasing the resonator from our control, we observed its rethermalization with nanosecond resolution. Extending circuit quantum electrodynamics to the megahertz regime, we have enabled the exploration of thermodynamics at the quantum scale and allowed interfacing quantum circuits with megahertz systems such as spin systems or macroscopic mechanical oscillators.