Limits on Preserving Quantum Coherence using Multi-Pulse Control

TL;DR

This paper establishes fundamental physical limits on quantum coherence preservation using multi-pulse control, introduces optimized sequences that approach these limits, and discusses implications for fault-tolerance in open quantum systems.

Contribution

It provides a non-perturbative upper bound on coherence achievable with pulsed dynamical decoupling under realistic timing constraints and introduces bandwidth-adapted sequences that saturate this bound.

Findings

Optimized control sequences outperform existing methods in realistic systems.

A fundamental upper bound on coherence preservation is established.

Reinforces the challenge of fault-tolerance in open quantum systems.

Abstract

We explore the physical limits of pulsed dynamical decoupling methods for decoherence control as determined by finite timing resources. By focusing on a decohering qubit controlled by arbitrary sequences of $\pi$-pulses, we establish a non-perturbative quantitative upper bound to the achievable coherence for specified maximum pulsing rate and noise spectral bandwidth. We introduce numerically optimized control "bandwidth-adapted" sequences that saturate the performance bound, and show how they outperform existing sequences in a realistic excitonic-qubit system where timing constraints are significant. As a byproduct, our analysis reinforces the impossibility of fault-tolerance accuracy thresholds for generic open quantum systems under purely reversible error control.