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Strongly correlated phenomena in cavity QED Fernando G.S.L. Brandão 1,2 Michael J. Hartmann 1,2 Martin B. Plenio 1,2 1 Institute for Mathematical Sciences,

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Presentation on theme: "Strongly correlated phenomena in cavity QED Fernando G.S.L. Brandão 1,2 Michael J. Hartmann 1,2 Martin B. Plenio 1,2 1 Institute for Mathematical Sciences,"— Presentation transcript:

1 Strongly correlated phenomena in cavity QED Fernando G.S.L. Brandão 1,2 Michael J. Hartmann 1,2 Martin B. Plenio 1,2 1 Institute for Mathematical Sciences, Imperial College London 2 QOLS, Blackett Laboratory, Imperial College London London, 04/05/2007

2 Cavity QED systems Strong Coupling: Non-trivial joint dynamics for atoms and photons

3 Array of coupled cavities Atoms in different cavities can “talk” to each other mediated by the photons Photons in the same cavity can “talk” to each other mediated by the atoms

4 Summary Photon nonlinearities EIT-based schemes Stark-shift based scheme Bose-Hubbard models Polaritons in coupled array of cavities The photonic limit Spin Chains Heisenberg model (XYZ)

5 Summary Photon nonlinearities EIT-based schemes Stark-shift based scheme Bose-Hubbard models Polaritons in coupled array of cavities The photonic limit Spin Chains Heisenberg model (XYZ)

6 Photon-Photon interactions Kerr-type nonlinear interaction: Several applications Photon blockade Imamoğlu et at, PRL 79, 1467 (1997) nonlinear optics Boyd, Nonlinear Optics, (1992) Quantum nondemolition measurents Imoto et al, PRA 32, 2287 (1985) Optical quantum computing Turchette et al, PRL 75, 4710 (1995) etc…

7 Photon-Photon interactions Kerr-type nonlinear interaction: Natural Kerr interactions are far too small …

8 Electromagnetically Induced Transparency nonlinearities 1 2 3 4     Imamo ğ lu et at, PRL 79, 1467 (1997) g h 

9 Electromagnetically Induced Transparency nonlinearities 1 2 3  g  N x

10 Electromagnetically Induced Transparency nonlinearities 1 2 3  g  N x

11 Electromagnetically Induced Transparency nonlinearities 1 2 3  g  N x

12 Electromagnetically Induced Transparency nonlinearities  h 1 2 3  g  4

13  h 1 2 3  g  4 Only dark state polaritons p 0 couple to level 4!

14 Electromagnetically Induced Transparency nonlinearities  h 1 2 3  g  4

15  h 2 3  g  4 1

16  h 2 3  g  4 1 We didn’t assume:  h

17 Electromagnetically Induced Transparency nonlinearities Example: Toroidal Microcavities Spillane et al, PRA 71, 013817 (2005) Aoki et al, Nature 443 671 (2006)

18 Electromagnetically Induced Transparency nonlinearities Example: Toroidal Microcavities Spillane et al, PRA 71, 013817 (2005) Aoki et al, Nature 443 671 (2006)

19 Could we find a simpler set-up producing a nonlinearity comparable with the EIT one?

20 A.C. Stark shift nonlinearity 1 2 3  g   

21 1 2 3  g    Dispersive regime:

22 A.C. Stark shift nonlinearity

23 Dispersive regime:

24 A.C. Stark shift nonlinearity Dispersive regime:

25 A.C. Stark shift nonlinearity - Same strength as EIT scheme - One level less

26 Summary Photon nonlinearities EIT-based schemes Stark-shift based scheme Bose-Hubbard model Polaritons in coupled array of cavities The photonic limit Spin Chains Heisenberg model (XYZ)

27 Bose Hubbard Model Fisher et al, PRB 40, 546 (1989)

28 Cold atoms in Optical Lattices Jaksch et al, PRL 81, 3108 (1998) Greiner et al, Nature 415, 39 (2002)

29 Cold atoms in Optical Lattices Jaksch et al, PRL 81, 3108 (1998) Greiner et al, Nature 415, 39 (2002)

30 The set-up

31 Photons can hope from one cavity to a neighbouring one Yariv et al, Optics Lett. 24, 711 (1999)

32 The polaritonic case  h 1 2 3  g  4

33  h 1 2 3  g  4

34

35

36

37 real pred.Fabry-Perot: 160 5 x 10 3 Photonic bgc: 10 5.5 x 10 5 MCs @ Imperial: 40 ?Micro-toroid: 53 5 x 10 6 Spillane et al, PRA 2005 Soda et al, Nature Materials 2005

38 The polaritonic case

39 The photonic case a.c. Stark shift nonlinearity EIT nonlinearity

40 The photonic case

41 real pred.Fabry-Perot: 2.6 10Photonic bgc: 0.1 4 x 10 3 MCs @ Imperial: 0.8 ?Micro-toroid: 2.6 1.25 x 10 5 Spillane et al, PRA 2005 Soda et al, Nature Materials 2005

42 Summary Photon nonlinearities EIT-based schemes Stark-shift based scheme Photonic Bose-Hubbard models Polaritons in coupled array of cavities The photonic limit Spin Chains Heisenberg model (XYZ)

43 Spins Lattices Open questions in condensed- matter physics: high T c superconductivity, frustration, etc… Applications in quantum information science: entanglement propagation, measurement-based quantum computation, etc…

44 Spins Lattices: Heisenberg (XYZ) model

45 XX and YY interactions: Spins Lattices: Heisenberg (XYZ) model

46 XX and YY interactions: Spins Lattices: Heisenberg (XYZ) model

47 XX and YY interactions: Spins Lattices: Heisenberg (XYZ) model

48 ZZ interactions + magnetic field: Spins Lattices: Heisenberg (XYZ) model

49 + Suzuki-Trotter Decomposition: Spins Lattices: Heisenberg (XYZ) model

50 Cluster state generation

51 Spins Lattices: XYZ model

52 real pred. real pred Fabry-Perot: 160 5 x 10 3 60 420 Photonic bc: 10 5.5 x 10 5 100 10 5 MCs @ Imperial: 40 ? 50 ?Micro-toroid: 53 5 x 10 6 20 400 Spillane et al, PRA 2005 Soda et al, Nature Materials 2005

53 References Nonlinearities: EIT scheme: Imamoğlu et at, PRL 79, 1467 (1997) Hartmann, Plenio, arXiv:0704.2575 Light shift scheme: Brandão, Hartmann, Plenio, arXiv:0705.xxxx Bose Hubbard model: Hartmann, Brandão, Plenio, Nature Physics 2, 849 (2006), quant-ph/0606097 Subsequent proposals: Angelakis, Santos, Bose, quant-ph/0606159 Greentree, Tahan, Cole, Hollenberg, Nature Physics 2, 856 (2006), quant-ph/0609050 Na, Utsonumiya, Tian, Yamamoto, quant-ph/0703219 Rossini, Fazio, Phase diagram of strongly correlated polaritons in a 1D array of coupled cavities, in preparation Spin Hamiltonians : Hartmann, Brand ã o, Plenio, arXiv:0704.3056

54 Thank you! Michael J. Hartmann Martin B. Plenio

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