Nonreciprocal microwave signal processing with a Field-Programmable Josephson Amplifier

Abstract

We report on the design and implementation of a Field Programmable Josephson Amplifier (FPJA) - a compact and lossless superconducting circuit that can be programmed in situ by a set of microwave drives to perform reciprocal and nonreciprocal frequency conversion and amplification. In this work we demonstrate four modes of operation: frequency conversion (-0.5~dB transmission, -30~dB reflection), circulation (-0.5~dB transmission, -30~dB reflection, 30~dB isolation), phase-preserving amplification (gain >20~dB, 1~photon of added noise) and directional phase-preserving amplification (-10~dB reflection, 18~dB forward gain, 8~dB reverse isolation, 1~photon of added noise). The system exhibits quantitative agreement with theoretical prediction. Based on a gradiometric Superconducting Quantum Interference Device (SQUID) with Nb/Al-AlOx/Nb Josephson junctions, the FPJA is first-order insensitive to flux noise and can be operated without magnetic shielding at low temperature. Due to its flexible design and compatibility with existing superconducting fabrication techniques, the FPJA offers a straightforward route toward on-chip integration with superconducting quantum circuits such as qubits or microwave optomechanical systems.