Designing reservoirs for 1/t decoherence of a qubit

TL;DR

This paper explores how specially engineered bosonic reservoirs with specific spectral densities can significantly delay qubit decoherence, offering new avenues for quantum technology applications.

Contribution

It introduces a novel reservoir engineering approach that leverages spectral densities with band edges to control and slow down qubit decoherence.

Findings

Exact analytical description of qubit dynamics using Fox H-functions.

Inverse power law decoherence with powers approaching unity over long times.

Reservoir design can effectively delay decoherence in quantum systems.

Abstract

Anomalous decoherence in the Jaynes-Cummings model emerges for a certain class of bosonic reservoirs, described by spectral densities with a band edge frequency coinciding with the qubit transition frequency. The special reservoirs are piecewise similar to those usually adopted in Quantum Optics, i.e., sub-ohmic at low frequencies and inverse power laws at high frequencies. The exact dynamics of the qubit is described analytically through Fox $H$-functions. Over estimated long time scales, decoherence results in inverse power laws with powers decreasing continuously to unity, according to the particular choice of the special reservoir. The engineering reservoir approach is a new way of strongly delaying the decoherence process with possible applications to Quantum Technologies, due to the simple form of the designed reservoirs.