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GAP Optique Geneva University 1 Quantum Communications at telecom wavelengths Nicolas Gisin Hugo Zbinden Toni Acin, Claudio Bareiro, Sylvain Fasel, J.-D.

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Presentation on theme: "GAP Optique Geneva University 1 Quantum Communications at telecom wavelengths Nicolas Gisin Hugo Zbinden Toni Acin, Claudio Bareiro, Sylvain Fasel, J.-D."— Presentation transcript:

1 GAP Optique Geneva University 1 Quantum Communications at telecom wavelengths Nicolas Gisin Hugo Zbinden Toni Acin, Claudio Bareiro, Sylvain Fasel, J.-D. Gautier, Ivan Marcikic, Hugues de Riedmatten, Valerio Scarani, André Stefanov, Damien Stucki, Sébastien Tanzilli, Robert Thew, Wolfgang Tittel, GAP-Optique, University of Geneva Q crypto over 67 km Time-bins:  high dimensions  robustness of non-maximally entangled qubits  Q teleportation at telecom

2 GAP Optique Geneva University 2 The plug&play setup Perfect interference (V  99%) without any adjustments, since: both pulses travel the same path in inverse order both pulses have exactly the same polarisation thanks to FM Alice Bob Drawback 1: Rayleigh backscattering Drawback 2: Trojan horse attacks

3 GAP Optique Geneva University 3 QC over 67 km, QBER  5% + aerial cable (in Ste Croix, Jura) !

4 GAP Optique Geneva University 4.Company established in 2001 –Spin-off from the University of Geneva.Products –Quantum Cryptography (optical fiber system) –Quantum Random Number Generator –Single-photon detector module (1.3  m and 1.55  m).Contact information email: info@idquantique.com web: http://www.idquantique.com

5 GAP Optique Geneva University 5 The qubit sphere and the time-bin qubit  qubit :  different properties : spin, polarization, time-bins  any qubit state can be created and measured in any basis variable coupler variable coupler 1 0   h AliceBob D 0 D 1 switch 1 0

6 GAP Optique Geneva University 6 entangled time-bin qubits  variable coupler B non-linear crystal 0 A 0 1 B 1 A  depending on coupling ratio and phase , maximally and non-maximally entangled states can be created

7 GAP Optique Geneva University 7 Arbitrary high dimensions Net visibility = 91 % ± 6 % Entanglement for a two-photon state of dimension at least : Quant-ph/0204165; QIC 2002

8 GAP Optique Geneva University 8 Partially Entangled Time-Bin Qubits R.T.Thew et al. quant-ph/0203067

9 GAP Optique Geneva University 9 Creation of a photonCreation of a qubitCreation of an entangled pair The Bell measurement teleportation setup Creation of any qubit to be teleported Analysis of the teleported qubit Coincidence electronics 3-fold 4-fold I. Marcikic et al., quant-ph/0205144

10 GAP Optique Geneva University 10 Bell measurement

11 GAP Optique Geneva University 11 Teleportation of a time-bin qubit equatorial states 2 photons +laser clock (1310&1550nm)  3 photons+laser clock Raw visibility : V raw =56 ± 5 % Fidelity for equatorial states : =78 ± 3 % Net visibility : V net =83 % ± 8%

12 GAP Optique Geneva University 12 Teleportation of a time-bin qubit North&South poles 80.5 % ± 3 %

13 GAP Optique Geneva University 13 Long distance quantum teleportation Teleported qubit analyzed after 2 km of optical fiber and 55 m of physical distance (separate labs)

14 GAP Optique Geneva University 14 Results for long distance teleportation North & south poles Fidelity for north&south poles : = 88 ± 3% = 77 ± 3% 81.2 % ± 2.5 % Fidelity for Q teleportation over 2km = 80.5 ± 2.5 % Equatorial states Raw visibility : V raw =61 ± 5 % Fidelity for equatorial states :

15 GAP Optique Geneva University 15 Quantum teleportation as Q repeater (even without Q memory) At telecom, the QBER is dominated by detector noise: AliceBob t , D AliceBob , D  AliceBob , D  Bell , D 2 2  = 0.1 det. efficiency; D = 10 dark count;  = 0.25 dB/km attenuation -4 N. Gisin et al., Rev.Mod.Phys. 74, 145-195, 2002

16 GAP Optique Geneva University 16 Conclusion  qubits and entangled qubits can be realized using time-bins.  entangled qudits in arbitrary high dimension d can be realized.  partially entangled qubits are robust over 11 km.  Q teleportation with:  telecom wavelength  two different crystals (spatially separated sources)  from one wavelength (1300 nm) to another (1550 nm)  first time with time-bins (ie insensitive to polarization fluctuations)  over 2 km of fiber and 55 meters of physical distance  mean fidelity :  81% both in the lab and at a distance = the possibility to teleport the "ultimate structure" of an object from one place to another, without the object ever being anywhere in between

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