Toward the Generation of Bell Certified Randomness Using Photons

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Transcription:

Toward the Generation of Bell Certified Randomness Using Photons Alessandro Cerè, Siddarth Koduru Josh, Chen Ming Chia, Jean-Daniel Bancal, Lana Sheridan, Valerio Scarani, Christian Kurtsiefer Quantum Optics Group 12/08/2013

Random is hard Randomness is hard to characterize statistical test can never complete Classical mechanics is deterministic there is no true randomness, only lack of knowledge. Quantum mechanics is based on randomness in real experiments we need to separate the genuine randomness from apparent randomness (noise, lack of knowledge).

Outline Certified randomness violating Bell inequality Bell s test with photons polarization Closing the detection loophole Locality loophole

Outline Certified randomness violating Bell inequality Bell s test with photons polarization Closing the detection loophole Locality loophole

Certification of randomness non local correlations of quantum states can be used to generate certified private randomness randomness private certified [*] S. Pironio et al., Nature 464, 1021 (2010)

Non local correlation: violation of Bell inequality X A Y B Source 45 Y A X B Alice Bob S = E(X A, X B ) E(X A, Y B )+E(Y A, X B )+E(Y A, Y B ) if S > 2 there is no local-realistic description for the observed correlation

Loopholes in the experimental violation Detection minimum necessary efficiency larger than 2 /3 Freedom of choice Locality random choice of the measurement basis spatial separation sufficient to exclude direct communication in the choice of the basis

Loopholes in the experimental violation 1998 locality (SPDC, fibres) locality and freedom of choice (SPDC) Tittel et al. Weihs et al. 2001 detection ( 9 Be + ions) Rowe et al. 2009 detection (Josephson phase qubits) Ansmann et al. 2013 detection (SPDC) detection (SPDC) Giustina et al. Christensen et al.

Outline Certified randomness violating Bell inequality Bell s test with photons polarization Closing the detection loophole Locality loophole

Optimal state for real detectors With finite detection efficiency the maximum violation is observed for a non-totally entangled state of the form: i = cos HV i + sin VHi with = ( ) and a set of measurement basis appropriately chosen: X a = {cos 1 H, sin 1 V } Y a = {cos 2 H, sin 2 V } X b = {cos 1 H, sin 1 V } Y b = {cos 2 H, sin 2 V } with 1, 2, 1, 2 functions of [*] P. H. Eberhard, Phys. Rev. A 47, R747 (1993)

Bell s test with two detectors Using an appropriate time binning it is possible to use only two detectors instead of four. For every time bin Alice and Bob assign a value to the measurement: -1 single detection event +1 no detection events multiple detection events The optimal time bin duration µ depends on the detected count rate.

Quantify randomness from Bell s violation Random bits per run 10 0 10 10 10 10 With CHSH, biased inputs (reference) From the correlations with biased inputs With CHSH and uniform choice of inputs From correlations and uniform choice of inputs 10 0.66 0.8 0.9 1 detectors efficiency We can extract more random bit per run than before.

Advantage of the new lower bound Unbiased choice of measurement basis Use of the full statistics (i.e. E s), not only the correlation S Efficiency compared to standard case 2.6 uniform basis, full statistics 2 uniform basis, CHSH 1.2 CHSH 1 0.66 biased inputs, full statistics 0.8 0.9 detectors 1 efficiency

Outline Certified randomness violating Bell inequality Bell s test with photons polarization Closing the detection loophole Locality loophole

Experimental setup i = cos HV i + e i sin VHi calcite fiber TES APD APD phase plate lens dichroic mirror HWP HWP HWP@ 45 calcite 405 nm crystal fiber TES HWP @ 45 dichroic mirror lens coincidence logic HWP PBS

Optimal pump focus for collection efficiency 1 pair efficiency 0.85 0.67 0.38 Corrected for detector efficiency AR coated fiber 0 0 100 170 200 300 400

Pairs efficiency = Measuring TES efficiency p C = 0.742 ± 0.007 S1 S 2 10000 8000 coincidence window 6000 4000 2000 0 0 0.5 1 1.5 2 Including an estimation of the losses ) TES efficiency > 0.93

Closing the detection loophole: table of efficiency pairs generation and collection 0.85 polarization projection 0.97 fiber transmission intrinsic 0.99 splices 0.94 detection 0.93 Total 0.71 > 0.667

Outline Certified randomness violating Bell inequality Bell s test with photons polarization Closing the detection loophole Locality loophole

Fast polarization modulator PBS control 0 1 V 0 200 control voltage MgO:LiNbO 3 PBS driver Detector 120 V 0 H L V drive voltage polarization

Timing considerations time (ns) Alice Bob signaling zone detection 315 250 basis choice 150 random number 115 photon pairs 0-50 -45 0 45 50m

Summary Using the full statistic we can extract more randomness Efficient source of polarization entangled photon pairs State of the art detection technologies allow us to overcome the detection loophole Fast polarization switch allows reasonable distances and rates Outlook Improve the detection speed Include the fast polarization switch in the setup

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