English

A quantum memory at telecom wavelengths

Quantum Physics 2020-08-11 v1 Optics

Abstract

Nanofabricated mechanical resonators are gaining significant momentum among potential quantum technologies due to their unique design freedom and independence from naturally occurring resonances. With their functionality being widely detached from material choice, they constitute ideal tools to be used as transducers, i.e. intermediaries between different quantum systems, and as memory elements in conjunction with quantum communication and computing devices. Their capability to host ultra-long lived phonon modes is particularity attractive for non-classical information storage, both for future quantum technologies as well as for fundamental tests of physics. Here we demonstrate such a mechanical quantum memory with an energy decay time of T12T_1\approx2 ms, which is controlled through an optical interface engineered to natively operate at telecom wavelengths. We further investigate the coherence of the memory, equivalent to the dephasing T2T_2^* for qubits, which exhibits a power dependent value between 15 and 112 μ\mus. This demonstration is enabled by a novel optical scheme to create a superposition state of 0+1\rvert{0}\rangle+\rvert{1}\rangle mechanical excitations, with an arbitrary ratio between the vacuum and single phonon components.

Keywords

Cite

@article{arxiv.1910.07409,
  title  = {A quantum memory at telecom wavelengths},
  author = {Andreas Wallucks and Igor Marinković and Bas Hensen and Robert Stockill and Simon Gröblacher},
  journal= {arXiv preprint arXiv:1910.07409},
  year   = {2020}
}
R2 v1 2026-06-23T11:45:32.810Z