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Classifying two-dimensional superfluids: why there is more to cuprate superconductivity than the condensation of charge -2e Cooper pairs cond-mat/0408329,

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Presentation on theme: "Classifying two-dimensional superfluids: why there is more to cuprate superconductivity than the condensation of charge -2e Cooper pairs cond-mat/0408329,"— Presentation transcript:

1 Classifying two-dimensional superfluids: why there is more to cuprate superconductivity than the condensation of charge -2e Cooper pairs cond-mat/0408329, cond-mat/0409470, and to appear Leon Balents (UCSB) Lorenz Bartosch (Yale) Anton Burkov (UCSB) Predrag Nikolic (Yale) Subir Sachdev (Yale) Krishnendu Sengupta (Toronto) MIT Chez Pierre December 13, 2004

2 Experiments on the cuprate superconductors show: Tendency to produce “density” wave order near wavevectors (2  /a)(1/4,0) and (2  /a)(0,1/4). Proximity to a Mott insulator at hole density  =1/8 with long-range “density” wave order at wavevectors (2  /a)(1/4,0) and (2  /a)(0,1/4). Vortex/anti-vortex fluctuations for a wide temperature range in the normal state STM studies of Ca 2-x Na x CuO 2 Cl 2 at low T, T. Hanaguri, C. Lupien, Y. Kohsaka, D.-H. Lee, M. Azuma, M. Takano, H. Takagi, and J. C. Davis, Nature 430, 1001 (2004). Measurements of the Nernst effect, Y. Wang, S. Ono, Y. Onose, G. Gu, Y. Ando, Y. Tokura, S. Uchida, and N. P. Ong, Science 299, 86 (2003). STM studies of Bi 2 Sr 2 CaCu 2 O 8+  above T c, M. Vershinin, S. Misra, S. Ono, Y. Abe, Y. Ando, and A. Yazdani, Science, 303, 1995 (2004).

3 Experiments on the cuprate superconductors show: Tendency to produce “density” wave order near wavevectors (2  /a)(1/4,0) and (2  /a)(0,1/4). Proximity to a Mott insulator at hole density  =1/8 with long-range “density” wave order at wavevectors (2  /a)(1/4,0) and (2  /a)(0,1/4). Vortex/anti-vortex fluctuations for a wide temperature range in the normal state Needed: A quantum theory of transitions between superfluid/supersolid/insulating phases at fractional filling, and a deeper understanding of the role of vortices

4 Outline A.Superfluid-insulator transitions of bosons on the square lattice at fractional filling Quantum mechanics of vortices in a superfluid proximate to a commensurate Mott insulator at filling f B.Extension to electronic models for the cuprate superconductors Dual vortex theories of the doped (1) Quantum dimer model (2)“Staggered flux” spin liquid

5 A. Superfluid-insulator transitions of bosons on the square lattice at fractional filling Quantum mechanics of vortices in a superfluid proximate to a commensurate Mott insulator at filling f

6 Bosons at filling fraction f  M. Greiner, O. Mandel, T. Esslinger, T. W. Hänsch, and I. Bloch, Nature 415, 39 (2002). Weak interactions: superfluidity Strong interactions: Mott insulator which preserves all lattice symmetries

7 Vortices proliferate as the superfluid approaches the insulator. In two dimensions, we can view the vortices as point particle excitations of the superfluid. What is the quantum mechanics of these “particles” ? Excitations of the superfluid: Vortices

8 In ordinary fluids, vortices experience the Magnus Force FMFM

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11 can be re-interpreted as a Lorentz force on a vortex “particle” due to a “magnetic” field B=h  So we need to consider the quantum mechanics of a particle moving in a “magnetic” field B and a periodic lattice potential --- the Hofstadter problem. At filling fraction f=1, the B field is such that there is exactly one flux quantum per unit cell. Such a B field is “invisible”, and the vortex “particle” moves in conventional Bloch waves

12 Bosons at filling fraction f  (equivalent to S=1/2 AFMs) Weak interactions: superfluidity C. Lannert, M.P.A. Fisher, and T. Senthil, Phys. Rev. B 63, 134510 (2001) S. Sachdev and K. Park, Annals of Physics, 298, 58 (2002)

13 Bosons at filling fraction f  (equivalent to S=1/2 AFMs) Weak interactions: superfluidity C. Lannert, M.P.A. Fisher, and T. Senthil, Phys. Rev. B 63, 134510 (2001) S. Sachdev and K. Park, Annals of Physics, 298, 58 (2002)

14 Bosons at filling fraction f  (equivalent to S=1/2 AFMs) Weak interactions: superfluidity C. Lannert, M.P.A. Fisher, and T. Senthil, Phys. Rev. B 63, 134510 (2001) S. Sachdev and K. Park, Annals of Physics, 298, 58 (2002)

15 Bosons at filling fraction f  (equivalent to S=1/2 AFMs) Weak interactions: superfluidity C. Lannert, M.P.A. Fisher, and T. Senthil, Phys. Rev. B 63, 134510 (2001) S. Sachdev and K. Park, Annals of Physics, 298, 58 (2002)

16 Bosons at filling fraction f  (equivalent to S=1/2 AFMs) Strong interactions: insulator C. Lannert, M.P.A. Fisher, and T. Senthil, Phys. Rev. B 63, 134510 (2001) S. Sachdev and K. Park, Annals of Physics, 298, 58 (2002)

17 Bosons at filling fraction f  (equivalent to S=1/2 AFMs) Strong interactions: insulator C. Lannert, M.P.A. Fisher, and T. Senthil, Phys. Rev. B 63, 134510 (2001) S. Sachdev and K. Park, Annals of Physics, 298, 58 (2002)

18 Quantum mechanics of the vortex “particle” in a periodic potential with f flux quanta per unit cell Vortices in a superfluid near a Mott insulator at filling f Space group symmetries of Hamiltonian:

19 Hofstadter spectrum of the quantum vortex “particle” with field operator  Vortices in a superfluid near a Mott insulator at filling f=p/q

20 Hofstadter spectrum of the quantum vortex “particle” with field operator  See also X.-G. Wen, Phys. Rev. B 65, 165113 (2002) Vortices in a superfluid near a Mott insulator at filling f=p/q

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24 Field theory with projective symmetry

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26 Spatial structure of insulators for q=2 (f=1/2) Field theory with projective symmetry

27 Spatial structure of insulators for q=4 (f=1/4 or 3/4) Field theory with projective symmetry

28 Any pinned vortex must chose an orientation in flavor space. This necessarily leads to modulations in the local density of states over the spatial region where the vortex executes its quantum zero point motion. Pinned vortices in the superfluid

29 100Å b 7 pA 0 pA Vortex-induced LDOS of Bi 2 Sr 2 CaCu 2 O 8+  integrated from 1meV to 12meV at 4K J. Hoffman, E. W. Hudson, K. M. Lang, V. Madhavan, S. H. Pan, H. Eisaki, S. Uchida, and J. C. Davis, Science 295, 466 (2002). Vortices have halos with LDOS modulations at a period ≈ 4 lattice spacings Prediction of VBS order near vortices: K. Park and S. Sachdev, Phys. Rev. B 64, 184510 (2001).

30 Measuring the inertial mass of a vortex

31 Note: With nodal fermionic quasiparticles, m v is expected to be dependent on the magnetic field i.e. vortex density G. E. Volovik, JETP Lett. 65, 217 (1997); N. B. Kopnin, Phys. Rev. B 57, 11775 (1998).

32 B. Extension to electronic models for the cuprate superconductors Dual vortex theories of the doped (1) Quantum dimer model (2)“Staggered flux” spin liquid

33 g = parameter controlling strength of quantum fluctuations in a semiclassical theory of the destruction of Neel order La 2 CuO 4 (B.1) Phase diagram of doped antiferromagnets

34 g La 2 CuO 4 or N. Read and S. Sachdev, Phys. Rev. Lett. 62, 1694 (1989). (B.1) Phase diagram of doped antiferromagnets T. Senthil, A. Vishwanath, L. Balents, S. Sachdev and M.P.A. Fisher, Science 303, 1490 (2004).

35 g La 2 CuO 4 or Dual vortex theory of doped dimer model for interplay between VBS order and d-wave superconductivity  Hole density (B.1) Phase diagram of doped antiferromagnets

36 (B.1) Doped quantum dimer model E. Fradkin and S. A. Kivelson, Mod. Phys. Lett. B 4, 225 (1990). Density of holes = 

37 (B.1) Duality mapping of doped quantum dimer model shows: Vortices in the superconducting state obey the magnetic translation algebra Most results of Part A on bosons can be applied unchanged with q as determined above

38 g La 2 CuO 4  Hole density (B.1) Phase diagram of doped antiferromagnets

39 g La 2 CuO 4  Hole density (B.1) Phase diagram of doped antiferromagnets

40 g La 2 CuO 4  Hole density (B.1) Phase diagram of doped antiferromagnets

41 g La 2 CuO 4  Hole density (B.1) Phase diagram of doped antiferromagnets d-wave superconductivity above a critical 

42 (B.2) Dual vortex theory of doped “staggered flux” spin liquid

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46 Superfluids near Mott insulators Vortices with flux h/(2e) come in multiple (usually q ) “flavors” The lattice space group acts in a projective representation on the vortex flavor space. These flavor quantum numbers provide a distinction between superfluids: they constitute a “quantum order” Any pinned vortex must chose an orientation in flavor space. This necessarily leads to modulations in the local density of states over the spatial region where the vortex executes its quantum zero point motion. Superfluids near Mott insulators Vortices with flux h/(2e) come in multiple (usually q ) “flavors” The lattice space group acts in a projective representation on the vortex flavor space. These flavor quantum numbers provide a distinction between superfluids: they constitute a “quantum order” Any pinned vortex must chose an orientation in flavor space. This necessarily leads to modulations in the local density of states over the spatial region where the vortex executes its quantum zero point motion. The Mott insulator has average Cooper pair density, f = p/q per site, while the density of the superfluid is close (but need not be identical) to this value

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