Exact amplitudes of parametric processes in driven Josephson circuits

TL;DR

This paper introduces a comprehensive method for calculating exact parametric process amplitudes in driven Josephson circuits, enabling detailed analysis and optimization of circuit designs for quantum applications.

Contribution

It provides a systematic normal-ordered expansion approach to derive formally exact amplitudes for various Josephson circuit configurations, including multi-mode systems and higher-harmonics models.

Findings

Exact amplitudes for driven SNAIL and SQUID circuits obtained.

Application to Kerr-cat qubit Hamiltonian parameter estimation.

Analysis of chaos emergence in Kerr-cat qubits.

Abstract

We present a general approach for analyzing arbitrary parametric processes in Josephson circuits within a single degree of freedom approximation. Introducing a systematic normal-ordered expansion for the Hamiltonian of parametrically driven superconducting circuits we present a flexible procedure to describe parametric processes and to compare and optimize different circuit designs for particular applications. We obtain formally exact amplitudes (`supercoefficients') of these parametric processes for driven SNAIL-based and SQUID-based circuits. The corresponding amplitudes contain complete information about the circuit topology, the form of the nonlinearity, and the parametric drive, making them, in particular, well-suited for the study of the strong drive regime. We present a closed-form expression for supercoefficients describing circuits without stray inductors and a tractable formulation for those with it. We demonstrate the versatility of the approach by applying it to the estimation of Kerr-cat qubit Hamiltonian parameters and by examining the criterion for the emergence of chaos in Kerr-cat qubits. Additionally, we extend the approach to multi-degree-of-freedom circuits comprising multiple linear modes weakly coupled to a single nonlinear mode. We apply this generalized framework to study the activation of a beam-splitter interaction between two cavities coupled via driven nonlinear elements. Finally, utilizing the flexibility of the proposed approach, we separately derive supercoefficients for the higher-harmonics model of Josephson junctions, circuits with multiple drives, and the expansion of the Hamiltonian in the exact eigenstate basis for Josephson circuits with specific symmetries.