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Non-Abelian Josephson effect and fractionalized vortices

Non-Abelian Josephson effect and fractionalized vortices. Wu-Ming Liu (刘伍明) ( Institute of Physics, CAS ) Email: wmliu@aphy.iphy.ac.cn. Supported by NSFC, MOST, CAS. Collaborators. Jiang-Ping Hu (Purdue Univ) An-Chun Ji Zhi-Bing Li (Zhongshan Univ) Ran Qi Qing Sun

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Non-Abelian Josephson effect and fractionalized vortices

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  1. Non-Abelian Josephson effect and fractionalized vortices Wu-Ming Liu(刘伍明) (Institute of Physics, CAS) Email: wmliu@aphy.iphy.ac.cn Supported by NSFC, MOST, CAS

  2. Collaborators • Jiang-Ping Hu (Purdue Univ) • An-Chun Ji • Zhi-Bing Li (Zhongshan Univ) • Ran Qi • Qing Sun • Xin-Cheng Xie (Oklahoma State Univ) • Xiao-Lu Yu • Yan-Yang Zhang • Fei Zhou (British Columbia Univ)

  3. Outline 1. Introduction 2. Non-Abelian Josephson effect 3. Josephson effect of photons 4. Localization 5. Fractionalized vortex 6. Outlook

  4. 1. Introduction 1.1. BEC ofideal gas 7Li 6Li

  5. 1.2. BEC in dilute gas

  6. 1.3. BEC near Feshbach resonance

  7. 1.4. BEC in optical lattices

  8. 1.5. Fermionic condensation

  9. 1.6. Molecule condensation? J.G. Danzl et al. Science 321, 1062 (2008)

  10. 2. Non-Abelian Jesephson effect R. Qi, X.L. Yu, Z.B. Li, W.M. Liu, Non-Abelian Josephson effect between two F=2 spinor Bose-Einstein condensates in double optical traps, Phys. Rev. Lett. 102, 185301 (2009)

  11. Abelian case: U(1) × U(1)  U(1) diagonal two goldstone modes  one gapless mode (goldstone mode) and one gapped mode (pseudo goldstone mode) Non-Abelian case: SO(N), U(1) × SO(N)… Multiple pseudo goldstone modes

  12. No Josephson effect U(1)XU(1) Nambu-Goldstone modes

  13. Josephson effect Single mode: U(1)XU(1) Nambu-Goldstone modes Many modes: S=1, U(1)XS(2); S=2, U(1)XSO(3) Pseudo Nambu-Goldstone modes

  14. Ground states of S=2 bosonFerromagnetic phaseAntiferromagnetic phaseCyclic phase

  15. Ferromagnetic phase U(1)XU(1) Nambu-Goldstone modes

  16. Antiferromagnetic phase U(1)XSO(3) Pseudo Nambu-Goldstone modes

  17. Cyclic phase U(1)XSO(3) Pseudo Nambu-Goldstone modes

  18. Antiferromagnetic phase m=0

  19. m=±2

  20. Fig. 2 The frequencies of pseudo Goldstone modes as a function of coupling parameter J in the case of antiferromagnetic phase.

  21. Cyclic phase m=±1 m=0,±2

  22. Fig. 3 The frequencies of pseudo Goldstone modes as a function of coupling parameter J in the case of cyclic phase.

  23. Experimental parameter • Rb-87, F=2 • AFM: c2<0, c1-c2/20>0 • Cyclic: c1>0, c2>0 • c1:0-10nK, c2:0-0.2nK, c0:150nK • fluctuation time scale-10ms • pseudo Goldstone modes:1-10nk

  24. Experimental signatures • Initiate a density oscillation • Detect time dependence of atom numbers in different spin component • ◆Measure density oscillation in each of spin components • Non-Abelian Josephson effect

  25. 3. Jesephson effect of photons A.C. Ji, Q. Sun, X. C. Xie, W. M. Liu, Josephson effects of photons in two weakly-inked microcavities, Phys. Rev. Lett. 102, 023602 (2009)

  26. Fig. 1 Experimental setup and control of coupling along resonator axis

  27. Fig. 2 Excitations of a polariton condensate

  28. Fig. 3 Chemical potential-current relation in polariton condensates

  29. 4. Localization J. Billy et al., Nature 453, 891 (2008).

  30. G. Roati et al., Nature 453, 895 (2008)

  31. Y.Y. Zhang, J.P. Hu, B.A. Bernevig, X.R. Wang, X.C. Xie, W.M. Liu, Localization and Kosterlitz-Thouless transition in disordered graphene, Phys. Rev. Lett. 102, 106401 (2009)

  32. A B B A A B

  33. Fig. 1 The scaling function

  34. Fig. 2 Typical configurations of local currents In (red arrows) and potential Vn (color contour) on two sides of K-T type MIT with N=56X32 sites, \xi=1:73a, nI=1% and EF=0:1t. (a) W=1:1t (delocalized); (b) W=2:9t (localized).

  35. 5. Half vortex A.C. Ji, W.M. Liu, J.L. Song, F. Zhou, Dynamical creation of fractionalized vortices and vortex lattices, Phys. Rev. Lett. 101, 010402 (2008)

  36. Dynamical creation of fractionalized vortices and vortex lattices Fig.1 Density and spin density of an individual half vortex Fig. 2 Interaction potentials between two half vortex

  37. Fig. 3 Creation of a half-quantum vortex. The bottom panel shows that a single half vortex is formed at t=600 ms after magnetic trap has been adiabatically switched off.

  38. (a) Creation of a triangular integer vortex lattice (b) A square half vortex lattice formation at t=1600 ms

  39. 6. Outlook

  40. Thanks!

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