Litcius/Paper detail

Driving superconducting qubits into chaos

Jorge Chávez-Carlos, Miguel Prado Reynoso, Rodrigo G. Cortiñas, Ignacio García-Mata, Víctor S. Batista, F. Pérez‐Bernal, Diego A. Wisniacki, Lea F. Santos

2024Quantum Science and Technology14 citationsDOI

Abstract

Abstract Kerr parametric oscillators are potential building blocks for fault-tolerant quantum computers. They can stabilize Kerr-cat qubits, which offer advantages toward the encoding and manipulation of error-protected quantum information. The recent realization of Kerr-cat qubits made use of the nonlinearity of transmon superconducting circuits and a squeezing drive. Increasing nonlinearities can enable faster gate times, but, as shown here, can also induce chaos and melt the qubit away. We determine the region of validity of the Kerr-cat qubit and discuss how its disintegration could be experimentally detected. The danger zone for parametric quantum computation is also a potential playground for investigating quantum chaos with driven superconducting circuits.

Topics & Concepts

CHAOS (operating system)QubitSuperconductivitySuperconducting quantum computingPhysicsQuantum mechanicsStatistical physicsComputer scienceComputer securityQuantumAdvanced Thermodynamics and Statistical MechanicsQuantum many-body systems