The relationship between costs for quantum error mitigation and non-Markovian measures

Abstract

Quantum error mitigation (QEM) has been proposed as an alternative method of quantum error correction (QEC) to compensate errors in quantum systems without qubit overhead. While Markovian gate errors on digital quantum computers are mainly considered previously, it is indispensable to discuss a relationship between QEM and non-Markovian errors because non-Markovian noise effects inevitably exist in most of the solid state systems. In this work, we investigate the QEM for non-Markovian noise, and show that there is a clear relationship between costs for QEM and non-Markovian measures. We exemplify several non-Markovian noise models to bridge a gap between our theoretical framework and concrete physical systems. This discovery may help designing better QEM strategies for realistic quantum devices with non-Markovian environments.