/China Researchers Set Distance Record in Quantum Memory Entanglement (via Qpute.com)

China Researchers Set Distance Record in Quantum Memory Entanglement (via Qpute.com)

Efforts to develop the necessary capabilities for building a practical ‘quantum-based’ internet have been ongoing for years. One of the biggest challenges is being able to maintain and manage entanglement of remote quantum memories over great distances. Last week a group of researchers from University of Science and Technology of China reported in Nature having successfully entangled quantum memories made from atomic ensembles and maintained entanglement over 22 kilometers of “field-deployed fiber” and 50 kilometers of coiled fiber in a lab.

This achievement of city-scale distance ‘transmission’ over fiber using atomic ensembles as quantum memory is a first and is catching attention. There’s an account of the work posted on New Scientist noting, “Individual photons have been entangled across distances exceeding 1000 kilometres, but for larger systems of particles, which hold more information, maintaining this entanglement is harder.” In their work, the researchers used ensembles of ~100 million cooled rubidium atoms in a vacuum chamber as quantum memory.

The use of atomic ensembles for quantum memory has been an active area for some time and presents characteristics that enhance on-demand entanglement but also are challenging to manage. The details of the newly reported approach are best read directly from the paper (Entanglement of two quantum memories via fibres over dozens of kilometres). In brief, the researcher created two separate ‘memory’ nodes in the same lab and were able to entangle them in a way not unlike what would be needed for signal repeater in a quantum internet. This excerpt is from the paper:

“A quantum internet that connects remote quantum processors should enable a number of revolutionary applications such as distributed quantum computing. Its realization will rely on entanglement of remote quantum memories over long distances. Despite enormous progress, at present the maximal physical separation achieved between two nodes is 1.3 kilometres, and challenges for longer distances remain. Here we demonstrate entanglement of two atomic ensembles in one laboratory via photon transmission through city-scale optical fibres.

“The atomic ensembles function as quantum memories that store quantum states. We use cavity enhancement to efficiently create atom-photon entanglement and we use quantum frequency conversion to shift the atomic wavelength to telecommunications wavelengths. We realize entanglement over 22 kilometres of field-deployed fibres via two-photon interference and entanglement over 50 kilometres of coiled fibres via single-photon interference. Our experiment could be extended to nodes physically separated by similar distances, which would thus form a functional segment of the atomic quantum network, paving the way towards establishing atomic entanglement over many nodes and over much longer distances.”

Shown below is a diagram of the experiment and caption from the paper.


Schematic of the remote entanglement generation between atomic ensembles Two quantum memory nodes (nodes A and B in one laboratory) are linked by fibres to a middle station for photon measurement. In each node, a ⁸⁷Rb atomic ensemble is placed inside a ring cavity. All atoms are prepared in the ground state at first. We first create a local entanglement between atomic ensemble and a write photon by applying a write pulse (blue arrow). Then the write-out photon is collected along the clockwise (anticlockwise) cavity mode and sent to the QFC module. With the help of a PPLN-WG chip and a 1,950-nm pump laser (green arrow), the 795-nm write-out photon is converted to the telecommunications O band (1,342 nm). The combination of a half-wave-plate (HWP) and a quarter-wave-plate (QWP) improves the coupling with the transverse magnetic polarized mode of the waveguide. After noise filtering, two write-out photons are transmitted through long fibres, interfered inside a beamsplitter and detected by two superconducting nanowire single-photon detectors (SNSPDs) with efficiencies of about 50% at a dark-count rate of 100 Hz. The effective interference in the middle station heralds two entangled ensembles. Fibre polarization controllers (PCs) and polarization beamsplitters (PBSs) before the interference beamsplitter (BS) are intended to actively compensate polarization drifts in the long fibre. To retrieve the atom state, we apply a read pulse (red arrow) counter-propagating to the write pulse. By phase-matching the spin-wave and cavity enhancement, the atomic state is efficiently retrieved into the anticlockwise (clockwise) mode of the ring cavity. DM refers to dichroic mirror, LP refers to long-pass filter and BP refers to band-pass filter.

The researchers note their work is an important first step and discuss next steps: “Extending these experiments to nodes separated by much longer distances will enable us to perform advanced quantum information tasks, such as efficient quantum teleportation over long distances. By incorporating more quantum memories, our experiment may be extended to entangle multiple quantum memories over long distances via multi-photon interference. One may also create two pairs of remote atomic entanglement over sub-links and extend the distance of atomic entanglement via entanglement swapping, following the quantum repeater scheme. Concatenating this process could extend the distance sufficiently to beat the limit of direct transmission.”

Link to New Scientist article written by Leah Crane: https://www.newscientist.com/article/2233317-record-breaking-quantum-memory-brings-quantum-internet-one-step-closer/#ixzz6EVDW1B4F

Link to Nature paper: https://www.nature.com/articles/s41586-020-1976-7.epdf

This is a syndicated post. Read the original post at Source link .