CQIQC-V -6 August, 03 Toronto Solid-state quantum communications and quantum computation based on single quantum-dot spin in optical microcavities Chengyong Hu and John G. Rarity Electrical & Electronic Engineering, University of Bristol United Kingdom chengyong.hu@bristol.ac.uk SSQN
Background: Semiconductor quantum dots for QIP Artificial atoms: QD, NV, superconductor QDs are scalable, compatible with semiconductor technology Flying qubit - photon Single photon sources Electrically /optically driven Indistinguishable Cavity-QED enhanced Entangled photon-pair sources Static qubit - electron spin Long electron spin times T ~ms, T ~µs Fast electron-spin cooling / manipulation Long hole spin times T ~ms, T >00ns Fast hole-spin cooling / manipulation Quantum gates Photon-photon /spin-spin interactions Turchette et al, PRL 75, 470(95 Loss et al, PRA 57, 0 (98 Imamoglu et al, PRL 83, 404 (98 Calarco et al, PRA 68, 030(03 Our work Yuan et al, Science, 95, 0 (0 Moreau et al, APL 79, 865 (0 Santori et al, Nature 49, 594 (0 Strauf et al, Nature Photon., 704 (07 Stevenson et al, Nature 439, 79 (06 Akopian et al, PRL 96, 3050(06 Dousse et al, Nature 466,7(0 Greilich et al, Science, 33, 34 (06 Atature et al, Science, 3, 55 (06 Xu et al, PRL 99, 09740 (07 Berezovsky et al, Science 30,349(08 Press et al, Nature 456, 8 (08 Press et al, Nature Photon. 4, 367(0 Gerardot et al, Nature 45, 44 (08 Brunner et al, Science 35, 70 (09 Ramsay et al, PRL 00, 9740(08 Photon-spin interaction Duan and Kimble, PRL 9,790(04 Yao et al, PRL 95, 030504(05 Bonato et al, PRL04, 60503(0 Hu et al, PRB 78, 085307 (08; ibid 78, 538 (08 Hu et al, PRB 80, 0536(09 Hu and Rarity, PRB 83, 5303(
3 Outline Giant optical Faraday rotation / Giant circular birefringence Photon-spin entangling gates: universal, deterministic, fast (~tens ps Conditional phase gate (type I π i ( L L + R R Uˆ ( π / = e Entanglement beam splitter (type II tˆ = rˆ = R R R R + + L L L L Single-photon based spin measurement, preparation, control Entanglement generation: photon-spin /spin-spin /photon-photon Photon-spin interfaces /spin memory Complete Bell-state analysers On-chip quantum repeaters Loophole-free Bell test Single-photon devices: switch, isolator, circulator, modulator, Conclusions 3
4 Giant Faraday rotation & photon-spin entangling gate (type I Heisenberg equations of motion Reflection coefficient (under weak-excitation limit Hu et al, Phys. Rev. B 78, 085307 (08 Giant optical Faraday rotation single-spin magneto-optical effect Spin, L-light feels a hot cavity and R-light feels a cold cavity Spin, R-light feels a hot cavity and L-light feels a cold cavity Large phase difference between cold and hot cavity ϕ0 ϕ θf = = θf Switch, isolator, circulator, router Quantum gates 4
5 Photon-spin entangling gate (type I Reflection operator Uˆ( ϕ = e i ϕ iϕh ( R R + L L + r ( ω e ( R R + L iϕ0 r ( ω = r ( ω e L 0 Phase shift operator [when r 0 (ω= r h (ω] ( L L + R R h ϕ is tunable between [-π, +π] ϕ=π/ can be achieved in Purcell and strong coupling regime if κ s /κ<.3 Ideal quantum measurement of spin Gate features Universal (conditional phase gate, or parity gate Unity efficiency High fidelity Fast (~ tens ps << spin decoherence time (~µs Hu et al, Phys. Rev. B 78, 085307 (08 5
6 Quantum non-demolition measurement of spin (type I Input photon H = ( R + L Spin Spin U& ( π / H U& ( π / H 0 + 45 45 0 Unity efficiency and fast(~tens ps Single-photon based H Spin projective measurement Spin initialisation Quantum feedback control Spin superposition state ( α U& ( π / + β ( α + 45 α + β 0 0 + β 45 Photon-spin entangler! Hu et al, Phys. Rev. B 78, 085307 (08 6
7 Spin entangler Photon entangler α ± i β α H ± iβ V Photon-spin quantum interface / spin memory (a Write in (b Read out Hu et al, Phys. Rev. B 78, 085307 (08; 78, 538(08 7
8 Complete Bell-state analyzer (type I Four Bell States Ψ ± Φ ± = = U ( π / Ψ U ( π / Φ ( R L ± L R / ( R R ± R R / ± ± + = i Ψ ± + = Φm + Spin measurements check parity Ψ ± and Φ ± Polarization measurements check phase Ψ + and Ψ -, Φ + and Φ - Complete and loss-resistant due to built-in spin memory No photon synchronization, no indistinguishability Global quantum networks via satellites Hu and Rarity, Phys. Rev. B 83, 5303( 8
9 Loss-resistant teleportation and entanglement swapping Three-step teleportation process (a On detecting photon, photon state is transferred to spin (b On detecting photon, spin and photon 3 get entangled (c On measuring spin, spin state is transferred to photon 3 Hu and Rarity, Phys. Rev. B 83, 5303( 9
0 Single-photon based spin control (type I Spin in, states giant optical Faraday rotation Photon in R, L states giant spin rotation one photon pulse in R or L π/ pulse U ( π / R ( α + β = R ( α + iβ U ( π / L ( α + β = L ( iα + β U ( π / R R ( α + β = R R ( α β U ( / L L ( α + β = L L ( α + β two photon pulses in R or L π pulse π Spin echo/dynamic decoupling to preserve the spin coherence π π ( π z compatible with QIP protocols x x Spin rotation around z with single photons Spin rotation around x with laser pulse (optical Stark effect or B in Voigt Hu and Rarity, Phys. Rev. B 83, 5303( 0
Giant circular birefringence & photon-spin entangling gate II universal, deterministic, fast(~tens ps In Purcell or strong coupling regime If, R-photon transmitted L-photon reflected If, R-photon reflected L-photon transmitted Transmission operator t ( ω t0( ω r ( ω r( ω ( R R + L L Reflection operator ( R R + L L t 0 ( ω 0, r ( ω 0 if κ s << κ Hu et al, PRB 80, 0536(09
Photon-spin entangler QND measurement of spin Entanglement beam splitter Photon-spin interface Hu et al, PRB 80, 0536(09 Spin entangler Photon entangler
3 Complete Bell-state Analyzer (type II Path measurements check parity Ψ ± and Φ ± Polarization measurements check phase Ψ + and Ψ -, Φ + and Φ - Complete and loss-resistant due to built-in spin memory No photon synchronization, no indistinguishability Global quantum networks via satellites Ψ ± + r t, t r r t r t t r [ L ± L L ] [ R L ± L L ] [ ] [ ] R Φ ± +, r t R t R t ± L r L r + R r R r ± L t L t Hu and Rarity, Phys. Rev. B 83, 5303( 3
4 On-chip quantum repeaters (two types Spin-cavity units as quantum repeaters Entanglement generation, swapping, purification and storage can all be performed with the spin-cavity units Global quantum networks via quantum repeaters Purification (type-i Purification (type-ii 4
5 Challenges for entanglement purification Quantum repeaters need gate errors on the percent level Gate imperfections Imperfect spin selection rules (error <0% Side-leakage from cavity Short spin dephasing time (~ns Solutions: spin echo/dynamic decoupling electron spin hole spin 5
9 Loophole-free Bell test (two types type-i type-ii Generate spin-spin entanglement via a single photon or photon-photon entanglement spin-spin entanglement Close detection loophole Single-photon based spin measurement with unity efficiency Close locality loophole Spin measurement time t < signal transfer time d/c t ~tens ps, d>3mm Device independent protocols, such as DIQKD, certified random number generation 6
7 Comparison of different cavity-qed systems with type-i gate in non-ideal case U( ϕ QD spin-cavity system is better than atom or NV for loopholefree Bell test N. Brunner et al, arxiv: 303.65(quan-ph 7
8 Entanglement generation with low-q microcavities (single-sided Non-deterministic scheme Suitable for QD-spin, NV Advantage: low-q, easy to implement Disadvantage: non-deterministic Young et al, Phys. Rev. A 87, 033( 8
9 Recent experimental progress with uncharged dots towards type-i gate Reflection spectroscopy Conditional phase shift interferometer D A V H = sin φ ( ω Young et al, Phys. Rev. A 84, 0803(R (0 9
0 Comparing PL and resonant spectroscopy Young et al, Phys. Rev. A 84, 0803(R (0 0
Conditional phase of 3 o observed between a dot on and off-resonance with cavity g~9.4uev κ+ κs ~ 6ueV γ~5uev g> (κ+ κs + γ/4 φ~ 3 o K K K K Young et al, Phys. Rev. A 84, 0803(R (0
Latest results from the laboratory Optical nonlinearity at ~0 photons per cavity lifetime Dot on resonance with a cavity studied in reflection We see a dot-cavity feature which saturates at 00nW If this is strongly coupled the timescale is that of the cavity decay, ie ~30ps Thus 00nW in 30ps gives optical nonlinearity at ~0 photons per cavity lifetime
3 Requirements to realize the photon-spin gates Charged QDs Modulation-doping Distinguish between charged and neutral excitons is non-trivial. High-quality microcavity Weak and strong coupling Low side leakage Spin initialization via spin measurement with single photons Spin control Rotation around z with single photons Rotation around x with laser pulse (optical Stark effect or B in Voigt Spin echo or dynamical decoupling to preserve spin coherence Compatible with QIP protocols 3
4 Summary and Outlook Two spin-cavity units photon-spin entangling gates Conditional photon-spin interaction GFR and GCB are optical linear effects Universal Deterministic (if optimized Fast (~tens ps Spin coherence time (µs > 00,000 gate time Single-photon based spin initialisation, measurement, and control BSM, repeaters, photon-spin interface/spin memory Realizable with current semiconductor technology Q=40,000 for d=.5 µm micropillars, Reitzenstein et al., APL 90, 509 (07 Purcell enhancement and strong coupling are achieved Global and secure quantum networks Via satellites or quantum repeaters Detection and locality loopholes can be closed simultaneously Practical solid-state quantum computers are possible DiVincenzo s criteria are all met! Single-photon devices: switch, isolator, circulator, router, Spin-cavity units can be applied in all aspects of QIP 4
Acknowledgements In collaborations with William J. Munro (NTT, Japan Jeremy L. O Brien (CQP, Bristol Nicolas Brunner (Bristol / Geneva Thanks for your attention! SSQN 5
6 6 Fidelity and Efficiency of BSA (Type I 0 0 ( ( ( ( ( 4 + = ± Φ ω ω ω ω r r r r F h h ( = ± Ψ F ( 0 ( ( 4 ω ω η + = h r r Hu and Rarity, Phys. Rev. B 83, 5303(