Entanglement and nonlocality between disparate solid-state quantum memories mediated by photons

Puigibert, Marcel.li Grimau; Askarani, Mohsen Falamarzi; Davidson, Jacob H.; Verma, Varun B.; Shaw, Matthew D.; Nam, Sae Woo; Lutz, Thomas; Amaral, Gustavo C.; Oblak, Daniel; Tittel, Wolfgang

doi:10.1103/physrevresearch.2.013039

Cited by 32 publications

(28 citation statements)

References 34 publications

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“…Hours long T 2 have even been observed when control techniques to decrease perturbations from the ions' environment are applied 7 . These outstanding properties have led to many demonstrations in the field of quantum memories for light including long time storage of single photons 8 , photonic entanglement storage 9 , and light to matter teleportation 10 . At the nanoscale, new possibilities appear based on coupling to optical and microwave micro-or nano-cavities for greatly enhanced interactions with light or accessing extreme sensitivities together with nanometer spatial resolution [11][12][13][14][15] .…”

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confidence: 99%

Defect Engineering for Quantum Grade Rare-Earth Nanocrystals

et al. 2020

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Nanostructured systems that combine optical and spin transitions offer new functionalities for quantum technologies by providing efficient quantum light-matter interfaces. Rare earth (RE) ions doped nanoparticles are promising in this field as they show long-lived optical and spin quantum states, a unique feature among nanomaterials. However, further development of their use in highly demanding applications such as scalable single ion based quantum processors, requires controlling defects that currently limit coherence lifetimes. In this work, we demonstrate that a novel posttreatment process that includes multi-step high-temperature annealing followed by high-power microwave oxygen plasma processing advantageously improves key properties for quantum technologies. We obtain single crystalline nanoparticles (NPs) of 100 nm diameter, presenting bulk-like inhomogeneous linewidths (Γ inh) and population lifetimes (T 1). Furthermore, a significant coherence lifetime (T 2) extension, up to a factor of 5, is successfully achieved by modifying the oxygen-related point defects in the NPs by the oxygen plasma treatment. These promising results confirm the potential of these engineered RE NPs to integrate devices such as cavity-based single photon sources, quantum memories and processors. In addition, our strategy could be applied to a large variety of oxides to obtain outstanding crystalline quality NPs for a broad range of applications.

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confidence: 99%

Defect Engineering for Quantum Grade Rare-Earth Nanocrystals

et al. 2020

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“…Entanglement is a specific kind of quantum correlations, and has been extensively studied for many systems [ 20 , 22 , 23 , 24 , 25 , 26 ]. It is linked to several applications in quantum information, such as quantum processing [ 27 ], key distribution [ 28 ], teleportation [ 29 ], cryptography [ 30 ], and quantum memory [ 31 , 32 ].…”

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confidence: 99%

Nonclassical Effects Based on Husimi Distributions in Two Open Cavities Linked by an Optical Waveguide

Mohamed

Eleuch

2020

Entropy

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Nonclassical effects are investigated in a system formed by two quantum wells, each of which is inside an open cavity. The cavities are spatially separated, linked by a fiber, and filled with a linear optical medium. Based on Husimi distributions (HDs) and Wehrl entropy, we explore the effects of the physical parameters on the generation and the robustness of the mixedness and HD information in the phase space. The generated quantum coherence and the HD information depend crucially on the cavity-exciton and fiber cavity couplings as well as on the optical medium density. The HD information and purity are lost due to the dissipation. This loss may be inhibited by increasing the optical susceptibility as well as the couplings of the exciton-cavity and the fiber-cavity. These parameters control the regularity, amplitudes, and frequencies of the generated mixedness.

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“…After passing through the crystal's h110i direction, the light is directed to a photodetector. This setup is used for AFC creation (see also [38]), initial memory characterization, and storage of optical pulses in a single spectral mode. For frequencymultiplexed storage and feed-forward recall, additional phase modulators are used to add frequency sidebands to the laser light, each of which creates a memory in a different spectral segment, and to frequency shift the light after reemission so that only the desired spectral mode passes through an optical filter cavity [6].…”

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“…To this end, we used 1-μs-long laser pulses (note that the use of true single photons would not change the results), and created AFCs with finesse F-the ratio between AFC peak spacing Δ and peak width δ-of 2. See [6,38] for more information. Tooth spacings varied between 100 and 10 kHz, corresponding to storage times between 10 and 100 μs, respectively.…”

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Long-Lived Solid-State Optical Memory for High-Rate Quantum Repeaters

et al. 2021

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We argue that long optical storage times are required to establish entanglement at high rates over large distances using memory-based quantum repeaters. Triggered by this conclusion, we investigate the 795.325 nm 3 H 6 ↔ 3 H 4 transition of Tm∶Y 3 Ga 5 O 12 (Tm:YGG). Most importantly, we find that the optical coherence time can reach 1.1 ms, and, using laser pulses, we demonstrate optical storage based on the atomic frequency comb protocol during up to 100 μs as well as a memory decay time T m of 13.1 μs. Possibilities of how to narrow the gap between the measured value of T m and its maximum of 275 μs are discussed. In addition, we demonstrate multiplexed storage, including with feed-forward selection, shifting and filtering of spectral modes, as well as quantum state storage using members of nonclassical photon pairs. Our results show the potential of Tm:YGG for creating multiplexed quantum memories with long optical storage times, and open the path to repeater-based quantum networks with high entanglement distribution rates.

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Entanglement and nonlocality between disparate solid-state quantum memories mediated by photons

Cited by 32 publications

References 34 publications

Defect Engineering for Quantum Grade Rare-Earth Nanocrystals

Defect Engineering for Quantum Grade Rare-Earth Nanocrystals

Nonclassical Effects Based on Husimi Distributions in Two Open Cavities Linked by an Optical Waveguide

Long-Lived Solid-State Optical Memory for High-Rate Quantum Repeaters

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