Designing Kerr Interactions for Quantum Information Processing via Counterrotating Terms of Asymmetric Josephson-Junction Loops

TL;DR

This paper develops a theoretical framework for engineering Kerr interactions in superconducting circuits with asymmetric Josephson-junction loops, enabling faster quantum operations without increasing unwanted anharmonicity.

Contribution

It introduces a perturbative approach to derive effective Hamiltonians, showing how higher-order nonlinearities can cancel Kerr effects and enhance quantum gate rates.

Findings

Effective Kerr couplings can be canceled by higher-order nonlinearities.

Cubic interactions increase operation rates without raising anharmonicity.

Analytical results are supported by numerical experiments.

Abstract

Continuous-variable systems realized in high-coherence microwave cavities are a promising platform for quantum information processing. While strong dynamic nonlinear interactions are desired to implement fast and high-fidelity quantum operations, static cavity nonlinearities typically limit the performance of bosonic quantum error-correcting codes. Here we study theoretical models of nonlinear oscillators describing superconducting quantum circuits with asymmetric Josephson-junctions loops. Treating the nonlinearity as a perturbation, we derive effective Hamiltonians using the Schrieffer-Wolff transformation. We support our analytical results with numerical experiments and show that the effective Kerr-type couplings can be canceled by an interplay of higher-order nonlinearities. This can be better understood in a simplified model supporting only cubic and quartic nonlinearities. Our results show that a cubic interaction allows to increase the effective rates of both linear and nonlinear operations without an increase in the undesired anharmonicity of an oscillator which is crucial for many bosonic encodings.