Broadband Squeezed Microwaves and Amplification with a Josephson Traveling-Wave Parametric Amplifier

Squeezing of the electromagnetic vacuum is an essential metrological technique that is used to reduce quantum noise in applications spanning gravitational wave detection, biological microscopy, and quantum information science. In circuit quantum electrodynamics, squeezed microwaves have been used to suppress radiative spontaneous emission from a superconducting qubit and to enhance the search for dark matter axions. However, the resonator-based Josephson junction parametric amplifiers conventionally used to generate squeezed microwaves are constrained by a narrow bandwidth and low dynamic range which limits their utility. In this work, we develop a dual-pump, broadband Josephson traveling-wave parametric amplifier (JTWPA) and use it to demonstrate a 56 dB phase-sensitive extinction ratio, $-11.35^{+1.57}_{-2.49}$ dB single-mode squeezing, and two-mode squeezing over a bandwidth of 1.75 GHz. The phase-sensitive extinction ratio is the highest reported value to date for Josephson-junction-based circuits and useful for qubit readout in quantum computing and phase regeneration in quantum communications. The achieved single-mode squeezing represents an order-of-magnitude reduction of vacuum noise, on par with the best resonator-based squeezers. We have furthermore demonstrated two-mode squeezing with the broadest bandwidth reported thus far at microwave frequencies. The JTWPA is capable of simultaneously creating entangled microwave photon pairs with a large frequency separation, enabling new possibilities for applications including high-fidelity qubit readout, quantum illumination and teleportation.