Long-time Low-latency Quantum Memory by Dynamical Decoupling
Abstract
Quantum memory is a central component for quantum information processing devices, and will be required to provide high-fidelity storage of arbitrary states, long storage times and small access latencies. Despite growing interest in applying physical-layer error-suppression strategies to boost fidelities, it has not previously been possible to meet such competing demands with a single approach. Here we use an experimentally validated theoretical framework to identify periodic repetition of a high-order dynamical decoupling sequence as a systematic strategy to meet these challenges. We provide analytic bounds-validated by numerical calculations-on the characteristics of the relevant control sequences and show that a "stroboscopic saturation" of coherence, or coherence plateau, can be engineered, even in the presence of experimental imperfection. This permits high-fidelity storage for times that can be exceptionally long, meaning that our device-independent results should prove instrumental in producing practically useful quantum technologies.
Cite
@article{arxiv.1206.6087,
title = {Long-time Low-latency Quantum Memory by Dynamical Decoupling},
author = {Kaveh Khodjasteh and Jarrah Sastrawan and David Hayes and Todd J. Green and Michael J. Biercuk and Lorenza Viola},
journal= {arXiv preprint arXiv:1206.6087},
year = {2013}
}
Comments
abstract and authors list fixed