Numerical analysis of a three-wave-mixing Josephson traveling-wave parametric amplifier with engineered dispersion loadings

Abstract

The recently proposed Josephson traveling-wave parametric amplifier (JTWPA) based on a ladder transmission line consisting of radio-frequency SQUIDs and exploiting three-wave mixing (3WM), has great potential in achieving both a gain of 20 dB and a flat bandwidth of at least 4 GHz. To realize this concept in practical amplifiers we model the advanced JTWPA circuit with periodic modulation of the circuit parameters (engineered dispersion loadings), which allow the basic mixing process, i.e., ωs=ωp-ωi, where ωs, ωp, and ωi are the signal, the pump, and the idler frequencies, respectively, and efficiently suppress propagation of unwanted higher tones including ω2p=2ωp, ωp+s=ωp +ωs, ωp+i = ωp + ωi, etc. The engineered dispersion loadings allow achieving sufficiently wide 3 dB-bandwidth from 3 GHz to 9 GHz combined with a reasonably small ripple (2 dB) in the gain-versus-frequency dependence.