Decoherence due to discrete noise in Josephson qubits

TL;DR

This paper models decoherence in Josephson qubits caused by discrete bistable fluctuators, especially addressing 1/f noise and its memory effects, to identify environmental factors affecting qubit coherence.

Contribution

It introduces a detailed model of environment-induced decoherence in Josephson qubits considering discrete noise sources and analyzes measurement procedures and environmental characterization.

Findings

Memory effects significantly influence decoherence dynamics.

Knowledge of one additional microscopic parameter often suffices to characterize environmental impact.

Different physical situations require different degrees of environmental information.

Abstract

We study decoherence produced by a discrete environment on a charge Josephson qubit by introducing a model of an environment of bistable fluctuators. In particular we address the effect of $1/f$ noise where memory effects play an important role. We perform a detailed investigation of various computation procedures (single shot measurements, repeated measurements) and discuss the problem of the information needed to characterize the effect of the environment. Although in general information beyond the power spectrum is needed, in many situations this results in the knowledge of only one more microscopic parameter of the environment. This allows to determine which degrees of freedom of the environment are effective sources of decoherence in each different physical situation considered.