Experimental emulation of quantum non-Markovian dynamics and coherence protection in the presence of information backflow

TL;DR

This paper demonstrates the experimental emulation of non-Markovian quantum dynamics in a spin system, investigates coherence protection via optimized dynamical decoupling sequences, and explores tuning of non-Markovianity through control techniques.

Contribution

It introduces a method to emulate non-Markovian environments in a controlled setting and optimizes dynamical decoupling sequences to protect quantum coherence.

Findings

Non-Markovian dynamics can be effectively emulated using RF fields.

Optimized DD sequences significantly improve coherence preservation.

Tuning of non-Markovianity is achievable via dynamical decoupling control.

Abstract

We experimentally emulate, in a controlled fashion, the non-Markovian dynamics of a pure dephasing spin-boson model at zero temperature. Specifically, we use a randomized set of external radio-frequency fields to engineer a desired noise power-spectrum to effectively realize a non-Markovian environment for a single NMR qubit. The information backflow, characteristic to the non-Markovianity, is captured in the nonmonotonicity of the decoherence function and von Neumann entropy of the system. Using such emulated non-Markovian environments, we experimentally study the efficiency of the Carr-Purcell-Meiboom-Gill dynamical decoupling (DD) sequence to inhibit the loss of coherence. Using the filter function formalism, we design optimized DD sequences that maximize coherence protection for non-Markovian environments and study their efficiencies experimentally. Finally, we discuss DD-assisted tuning of the effective non-Markovianity.