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  • 日本語トップ

Highly Efficient Entanglement Swapping and Teleportation at Telecom Wavelength

- NICT demonstrates three orders higher count rates -

  • 日本語
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March 26, 2015

    • The entanglement swapping and teleportation were realized with approximately 1,000 times higher count rates than traditional schemes at telecom wavelengths.
    • This novelty was realized by combining our highly efficient entangled photon sources and highly efficient superconducting nanowire single photon detectors.
    • This research will accelerate the practical use of entanglement swapping and quantum teleportation based communication protocols at telecom wavelengths.

Abstract

NICT, in collaboration with the University of Electro-Communications (UEC, President: Dr. Takashi Fukuda), has succeeded in the demonstration of highly efficient entanglement swapping and teleportation at telecom wavelength. We have attained a four-fold coincidence count rate of 108 counts per second, which is three orders higher than the previous experiments at telecom wavelengths. This experiment opens the way to practical implementation of device-independent quantum key distribution and its distance extension by the entanglement swapping as well as multi-photon entangled state generation in telecom band infrastructures with both space and fiber links.
The result was published in Scientific Reports (Nature Publishing Group) on March 20, 2015.

Background

Entanglement swapping at telecom wavelengths is at the heart of quantum networking in optical fiber infrastructures. Although entanglement swapping has been demonstrated experimentally so far using various types of entangled photon sources in telecom wavelength regions, the rate of swapping operation has been too low to be applied to practical quantum protocols, due to the limited efficiency of entangled photon sources and photon detectors.

Achievements
The experimental setup
The experimental setup

Here we have demonstrated drastic improvement of the efficiency at telecom wavelength by using two ultra-bright entangled photon sources and four highly efficient superconducting nanowire single photon detectors. We have attained a four-fold coincidence count rate of 108 counts per second, which is three orders higher than the previous experiments at telecom wavelengths. A raw (net) visibility in a Hong-Ou-Mandel interference between the two independent entangled sources was 73.3% (85.1%). We performed the teleportation and entanglement swapping, and obtained a fidelity of 76.3% in the swapping test.

Future Prospects

Our scheme opens the way to practical implementation of device-independent quantum key distribution and its distance extension by the entanglement swapping as well as multi-photon entangled state generation in telecom band infrastructures with both space and fiber links.

Journal:  Scientific Reports (Nature Publishing Group), DOI: 10.1038/srep09333
URL:       http://www.nature.com/scientificreports
Title:       Highly efficient entanglement swapping and teleportation at telecom wavelength
Authors:  Rui-Bo Jin, Masahiro Takeoka, Utako Takagi, Ryosuke Shimizu, and Masahide Sasaki



Appendix

Figure 1: The experimental setup
Figure 1: The experimental setup [Click picture to enlarge]

The experimental setup: Picosecond laser pulses (76 MHz, 792 nm, temporal duration of about 2 ps) from a mode-locked Titanium sapphire laser (Mira900) pumped two PPKTP- Sagnac-entangled photon sources. The photons were detected by superconducting nanowire single photon detectors. (a) is for entangled source test. (b) is for Hong-Ou-Mandel interference test. (c) is for teleportation test. (d) is for entanglement swapping test.

Figure 2: The entanglement swapping results
Figure 2: The entanglement swapping results [Click picture to enlarge]

The entanglement swapping results: (a) with 80 mW pump power for entangled source I (II). (b) the power was reduced to 40 mW for entangled source I (II). The background subtracted visibilities (raw visibilities) are shown on the right side. The error bars were added by assuming Poissonian statistics of these coincidence counts.



Technical Contact

Rui-Bo Jin
Quantum ICT Laboratory
Advanced ICT Research Institute
Tel: +81-42-327-5603
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Sachiko Hirota
Public Relations Department
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