During the last decades, superconducting quantum circuits have shown impressive results fueled by the so-called circuit Quantum ElectroDynamics (cQED) architecture where the quantum signal is carried by photons at microwave frequencies. cQED experiments often rely on the technology of aluminum Josephson Junctions (JJ's) which can be understood as non-linear inductors. This non-linearity allowed the development of numerous non-linear lossless microwave components (tunable resonators [1], low noise amplifier [2] ...) which became essential tools for state-of-the-art cQED experiments. Yet, as a consequence of being built upon aluminum JJ's, all of these components are restricted to low magnetic field ≲ 250mT, temperature ≲ 250mK and frequency ≲ 10 GHz, strongly limiting the range of their application. The use of disordered superconductors with a large superconducting gap such as NbN would alleviate these constraints by one order of magnitude.

The goal of the project is to demonstrate that the non‐linearity of large gap disordered superconductors, here NbN, can advantageously replace Al JJ’s in order to offer lossless microwave components to research communities working at large magnetic field [3] ∼ 6 T, temperature ∼ 4 K and frequency ∼ 100 GHz.

[1] Appl. Phys. Lett. 92, 203501, 2008

[2] Appl. Phys. Lett. 118, 142601, 2021

[3] Appl. Phys. Lett. 118, 054001, 2021