Efficient Coherent Control by Optimized Sequences of Pulses of Finite Duration

TL;DR

This paper introduces an optimized sequence of finite-duration control pulses for quantum systems to enhance long-term state storage, with rigorous derivation and minimal correction terms, applicable in experimental settings.

Contribution

It presents a mathematically rigorous optimized pulse sequence for quantum coherence preservation, accounting for finite pulse durations and amplitudes, improving upon previous idealized models.

Findings

Corrections are of order T^{N+1} and τ'^{3} without mixed terms.

Proposes a concrete experimental setup for verification.

Sequence enhances quantum state storage fidelity.

Abstract

Reliable long-time storage of arbitrary quantum states is a key element for quantum information processing. In order to dynamically decouple a spin or quantum bit from a dephasing environment, we introduce an optimized sequence of $N$ control pulses of finite durations $\tau\pp$ and finite amplitudes. The properties of this sequence of length $T$ stem from a mathematically rigorous derivation. Corrections occur only in order $T^{N+1}$ and $\tau\pp^3$ without mixed terms such as $T^N\tau\pp$ or $T^N\tau\pp^2$. Based on existing experiments, a concrete setup for the verification of the properties of the advocated realistic sequence is proposed.