Presentation is loading. Please wait.

Presentation is loading. Please wait.

GAP Optique Geneva University 1 Quantum Communication  With 1 photon: Q cryptography  With 2 photons: Q crypto, Bell tests, qutrits, plasmons  With.

Published byCorey Barnett Modified over 8 years ago

Similar presentations

Presentation on theme: "GAP Optique Geneva University 1 Quantum Communication  With 1 photon: Q cryptography  With 2 photons: Q crypto, Bell tests, qutrits, plasmons  With."— Presentation transcript:

1 GAP Optique Geneva University 1 Quantum Communication  With 1 photon: Q cryptography  With 2 photons: Q crypto, Bell tests, qutrits, plasmons  With 3 photons: Q teleportation  With 4 photons: entanglement swapping  News from the industry forehead Nicolas Gisin Hugo Zbinden, Ivan Marcikic, Hugues de Riedmatten, Sylvain Fasel, Jeroen van Houwelingen, Rob Thew Group of Applied Physics, University of Geneva

2 GAP Optique Geneva University 2 Q communication in optical fibres  The transmission depends on the wavelength - Lower attenuation : 1310 nm (0.3 dB/km) and 1550 nm (0.2dB/km) (telecom wavelengths) Two problems : Losses and decoherence. How to minimize them ?  Time-bin coding with  Decoherence due to birefringence : Polarization Mode Dispersion photons at telecom wavelength

3 GAP Optique Geneva University 3 Time-bin qubits  qubit :  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 State preparation Projective measurement W. Tittel & G. Weihs, Quant. Inf. Comput. 1, Number 2, 3 (2001)

4 GAP Optique Geneva University 4 B 0 A 0 1 B 1 A    Detectors & Coincidence   Time-bin entanglement PDC  Laser Variable coupler Robust against decoherence in optical fibers After 2x2km of optical fibers 2 km optical fibers V net =96%.Photon pair creation in a non-linear crystal.Parametric down-conversion (PDC).Energy and momentum conservation p =710nm s =1310nm i =1550nm R. Thew et al., Phys. Rev. A 66, 062304 (2002)

5 GAP Optique Geneva University 5 1-photon: Q crypto AliceBob 2- 31 km Results: (PRA 63,012309, 2001 and S. Fasel et al., EJPD 30, 143, 2004) CDC IF Asynchronous heralded single-photon source Time between a click at detector A and a click at detector B [# trigger signals] Number of events (normailzed) P(1 )=60% P(2 )=0.02% g (2) (0)=0.0012 34 KHz (quant-ph/0408136)

6 GAP Optique Geneva University 6 2-photons: Bell test over 50 km Bob Alice Time arrival on A 1 Time arrival on B 1 = short path = long path Type I NLC Creating photons @ 1.3 & 1.55  m deterministic sepation with WDM coupler

7 GAP Optique Geneva University 7  Idea: verify from time to time the phase Stabilisation of the interferometers Every 100 s the phase is brought back to a given value

8 GAP Optique Geneva University 8 Bell test over 50 km  With phase control we can choose four different settings  = 0 ° or 90 ° and  = -45 ° or 45 °  Violation of Bell inequalities: Violation of Bell inequalities by more than 15  Marcikic et al., PRL, in press, quant-ph/0404124

9 GAP Optique Geneva University 9 2-photons: Qutrit Entanglement

10 GAP Optique Geneva University 10 Bell Violation with qutrits I = 2.784 +/- 0.023 I(lhv) = 2 < I(2) = 2.829 < I(3) = 2.872

11 GAP Optique Geneva University 11 2-photons: Plasmon assisted entanglement transfer In collaboration with Prof. Erni, Zürich  a short lived phenomenon like a plasmon can be coherently excited at two times that differ by much more than its lifetime. At a macroscopic level this would lead to a “Schrödinger cat” living at two epochs that differ by much more than a cat’s lifetime.

12 GAP Optique Geneva University 12 3 photons: Q teleportation & Q relays  EPR  Bell 2 bits U  J. D. Franson et al, PRA 66,052307,2002 Collins et al., quant-ph/0311101

13 GAP Optique Geneva University 13 Q repeaters & relays * entanglement * Bell measurement.. QND measurement + Q memory * entanglement * Bell measurement. ?? REPEATER RELAY H. Briegel, W. Dür, J. I. Cirac and P. Zoller, Phys. Rev. Lett. 81, 5932 (1998) J. D. Franson et al, PRA 66,052307,2002; D. Collins et al., quant-ph/0311101

14 GAP Optique Geneva University 14 2 km of optical fiber Alice Alice:creation of qubits to be teleported Alice 55 m Bob Bob:analysis of the teleported qubit, 55 m from Charlie Bob Charlie Charlie:the Bell measurement Charlie fs laser @ 710 nm Experimental setup creation of entangled qubits coincidence electronics & LBO RG WDM RG WDM Ge InGaAs LBO BS InGaAs f s l a s e r sync out 1. 3 m  1. 3 m  1. 5 m  1. 5 m  2km H. de Riedmaten et al., PRL 92, 047904-1/4, 2004 I. Marcikic et al., Nature, 421, 509-513, 2003

15 GAP Optique Geneva University 15results Equatorial states Raw visibility : V raw = 55 ± 5 % = 77.5 ± 2.5 % = 78 ± 3% = 77 ± 3% North & south poles mean fidelity: F poles =77.5 ± 3 % 77.5 ±2.5 % Mean Fidelity » 67 % (no entanglement)

16 GAP Optique Geneva University 16 2 km of optical fiber Alice Alice:creation of qubits to be teleported Alice 55 m Bob Bob:analysis of the teleported qubit, 55 m from Charlie Bob Charlie Charlie:the Bell measurement Charlie fs laser @ 710 nm Experimental setup creation of entangled qubits coincidence electronics & LBO RG WDM RG WDM Ge InGaAs LBO BS InGaAs f s l a s e r sync out 1. 3 m  1. 3 m  1. 5 m  1. 5 m  2km H. de Riedmaten et al., PRL 92, 047904-1/4, 2004 On the same spool ! See Halder et al quant-ph/0408092

17 GAP Optique Geneva University 17 4-photons: Entanglement swapping Bell state measurement Entangled photons that never interacted EPR source

18 GAP Optique Geneva University 18 Sources of time-bin entangled photons The experiment Bell state measurement Entanglement analysis Actively stabilized interferometers  1km

19 GAP Optique Geneva University 19 In the experiment :Partial Bell state measurement Entanglement swapping Four Bell states involved in the experiment !

20 GAP Optique Geneva University 20 Superposition basis: results V = (80 ± 4) % F  90 % 78 hours of measurement !

21 GAP Optique Geneva University 21 Results: computational basis Mean Fidelity =

22 GAP Optique Geneva University 22 News from the industry forehead http://www.swissquantum.deckpoint.ch/embargo/index_en.php Yesterday, September 29, id Quantique, DeckPoint and the University of Geneva officially inaugurated the first data archive site secured with Quantum Cryptography.

23 GAP Optique Geneva University 23 Data archiving network secured by Quantum Crypto  10 km http://www.swissquantum.deckpoint.ch/embargo/index_en.php

24 GAP Optique Geneva University 24 Quantis: Quantum random numbers on demand (www.randomnumbers.info) 4 Mbit/s per module, up to 4 modules on one PC card 1 light source 1 beam splitter 2 photon counters in a few cm 3 (  4x5x1 cm 3 ) !!! www. idquantique.com

25 GAP Optique Geneva University 25 Few « qubit » Applications Photon-counting OTDR Coherent Q measurement of the degree of polarization: 020406080100120 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 symbole plein: polarimètre symbole vide: projection sur  (-) DOP=1 DOP=0.74 DOP=0.34 DOP temps(s) J.Lightwave Tech, 2, 390, 2004 PRL 91, 167902, 2003

26 GAP Optique Geneva University 26 Conclusions Where are the applications? Next September 29, id Quantique, DeskPoint and the University of Geneva will officially inaugurate the first data archive site secured with Quantum Cryptography.

27 GAP Optique Geneva University 27 Single Photon Sources 919 nm / 0.7 nm 650 nm / >50 nm 1550 nm / 7nm /  Quantum Dot NV High pump Low pump 271.40.12g (2) (0) [%] 0.040.0020.30.02P 2 [%] 8.32.260 P 1 [%] 76 MHz5.3 MHz803 kHz34 kHzNTNT Beveratos et. al., PRL 89, 187901 (2002) Vuckovic et. al., APL 82, 3596 (2003) Fasel et. al. in preparation

28 GAP Optique Geneva University 28 Size of the classical communication One proton in one cm 3 at a temperature of 300 K:  bits 10 20 protons in one cm 3 at a temperature of 300 K  10 20 x 155  10 22 bits To be compared to today’s optical fiber communication in labs: 1 Tbyte x 1024 WDW channels x 1000 fibers  10 19 bits/sec.   1 hour !! bits

29 GAP Optique Geneva University 29 entangled time-bin qubit  variable coupler non-linear crystal B s A s l B l A depending on coupling ratio and phase , maximally and non-maximally entangled states can be create d R. Thew et al, PRA 66, 062304, 2002 Extensions to entanglement in higher dimensions: - qutrits: R. Thew et al, quant-ph/0307122 - up to dimesnion 20: H. Deriedmatten et al, quant-ph/0309058

30 GAP Optique Geneva University 30 Bell state measurement H. Weinfurter, Europhysics Letters 25, 559-564 (1994) H. de Riedmatten et al., Phys. Rev. A 67, 022301 (2003) 1 2 A B

Download ppt "GAP Optique Geneva University 1 Quantum Communication  With 1 photon: Q cryptography  With 2 photons: Q crypto, Bell tests, qutrits, plasmons  With."

Similar presentations

Quantum Cryptography Post Tenebras Lux!

Quantum Cryptography Post Tenebras Lux!
WP 3 WP 3 – Quantum Repeaters Časlav Brukner

WP 3 WP 3 – Quantum Repeaters Časlav Brukner
Parametric Down-conversion and other single photons sources December 2009 Assaf Halevy Course # 77740, Dr. Hagai Eisenberg 1.

Parametric Down-conversion and other single photons sources December 2009 Assaf Halevy Course # 77740, Dr. Hagai Eisenberg 1.
Alfred U’Ren Daryl Achilles Peter Mosley Lijian Zhang Christine Silberhorn Konrad Banaszek Michael G. Raymer Ian A. Walmsley The Center for Quantum Information.

Alfred U’Ren Daryl Achilles Peter Mosley Lijian Zhang Christine Silberhorn Konrad Banaszek Michael G. Raymer Ian A. Walmsley The Center for Quantum Information.
Implementation of Practically Secure Quantum Bit Commitment Protocol Ariel Danan School of Physics Tel Aviv University September 2008.

Implementation of Practically Secure Quantum Bit Commitment Protocol Ariel Danan School of Physics Tel Aviv University September 2008.
Experimental work on entangled photon holes T.B. Pittman, S.M. Hendrickson, J. Liang, and J.D. Franson UMBC ICSSUR Olomouc, June 2009.

Experimental work on entangled photon holes T.B. Pittman, S.M. Hendrickson, J. Liang, and J.D. Franson UMBC ICSSUR Olomouc, June 2009.
Quantum Coherent Control with Non-classical Light Department of Physics of Complex Systems The Weizmann Institute of Science Rehovot, Israel Yaron Bromberg,

Quantum Coherent Control with Non-classical Light Department of Physics of Complex Systems The Weizmann Institute of Science Rehovot, Israel Yaron Bromberg,
Ilja Gerhardt QUANTUM OPTICS CQT GROUP Ilja Gerhardt, Matthew P. Peloso, Caleb Ho, Antía Lamas-Linares and Christian Kurtsiefer Entanglement-based Free.

Ilja Gerhardt QUANTUM OPTICS CQT GROUP Ilja Gerhardt, Matthew P. Peloso, Caleb Ho, Antía Lamas-Linares and Christian Kurtsiefer Entanglement-based Free.
GAP Optique Geneva University 1 Quantum Communication Nicolas Gisin  Quantum cryptography: BB84 and uncertainty relations Ekert and entanglement no cloning.

GAP Optique Geneva University 1 Quantum Communication Nicolas Gisin  Quantum cryptography: BB84 and uncertainty relations Ekert and entanglement no cloning.
GAP Optique 1 Quantum Communication  Quantum cryptography: a beautiful idea!  Quantum cryptography on a “black-board”  Quantum cryptography below lake.

GAP Optique 1 Quantum Communication  Quantum cryptography: a beautiful idea!  Quantum cryptography on a “black-board”  Quantum cryptography below lake.
Technion – Israel Institute of Technology, Physics Department and Solid State Institute Entangled Photon Pairs from Semiconductor Quantum Dots Nikolay.

Technion – Israel Institute of Technology, Physics Department and Solid State Institute Entangled Photon Pairs from Semiconductor Quantum Dots Nikolay.
Economic Stimulus : Valorization of Single Photon Detectors and Quantum Key Distribution Systems Hugo Zbinden Group of Applied Physics (GAP), UNIGE NCCR.

Economic Stimulus : Valorization of Single Photon Detectors and Quantum Key Distribution Systems Hugo Zbinden Group of Applied Physics (GAP), UNIGE NCCR.
Niels Bohr Institute Copenhagen University Quantum memory and teleportation with atomic ensembles Eugene Polzik.

Niels Bohr Institute Copenhagen University Quantum memory and teleportation with atomic ensembles Eugene Polzik.

Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 3.

Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 3.
Universal Optical Operations in Quantum Information Processing Wei-Min Zhang ( Physics Dept, NCKU )

Universal Optical Operations in Quantum Information Processing Wei-Min Zhang ( Physics Dept, NCKU )
Quantum Entanglement and Bell’s Inequalities Kristin M. Beck and Jacob E. Mainzer Demonstrating quantum entanglement of photons via the violation of Bell’s.

Quantum Entanglement and Bell’s Inequalities Kristin M. Beck and Jacob E. Mainzer Demonstrating quantum entanglement of photons via the violation of Bell’s.

Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 5.

Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 5.
Www.bris.ac.uk Single photon sources. Attenuated laser = Coherent state Laser Attenuator Approximate single photon source Mean number of photon per pulse.

Single photon sources. Attenuated laser = Coherent state Laser Attenuator Approximate single photon source Mean number of photon per pulse.

Similar presentations

Ads by Google