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Quantum phase transitions

Quantum phase transitions. http://onsager.physics.yale.edu/c41.pdf cond-mat/0109419. Quantum Phase Transitions Cambridge University Press. E. E. g. g. Avoided level crossing which becomes sharp in the infinite volume limit: second -order transition. True level crossing:

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Quantum phase transitions

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  1. Quantum phase transitions • http://onsager.physics.yale.edu/c41.pdf • cond-mat/0109419 Quantum Phase Transitions Cambridge University Press

  2. E E g g Avoided level crossing which becomes sharp in the infinite volume limit: second-order transition True level crossing: Usually a first-order transition What is a quantum phase transition ? Non-analyticity in ground state properties as a function of some control parameter g

  3. Why study quantum phase transitions ? T Quantum-critical • Theory for a quantum system with strong correlations: describe phases on either side of gc by expanding in deviation from the quantum critical point. Important property of ground state at g=gc : temporal and spatial scale invariance; characteristic energy scale at other values of g: gc g • Critical point is a novel state of matter without quasiparticle excitations • Critical excitations control dynamics in the wide quantum-critical region at non-zero temperatures.

  4. Outline • Quantum Ising Chain • Landau-Ginzburg-Wilson theory Mean field theory and the evolution of the excitation spectrum. • Superfluid-insulator transition Boson Hubbard model at integer filling. • Tilting the Mott insulator Density wave order at an Ising transition. • Bosons at fractional filling Beyond the Landau-Ginzburg-Wilson paradigm.

  5. I. Quantum Ising Chain

  6. I. Quantum Ising Chain 2Jg

  7. Full Hamiltonian leads to entangled states at g of order unity

  8. Experimental realization LiHoF4

  9. Lowest excited states: Coupling between qubits creates “flipped-spin” quasiparticle states at momentum p p Entire spectrum can be constructed out of multi-quasiparticle states Weakly-coupled qubits Ground state:

  10. S. Sachdev and A.P. Young, Phys. Rev. Lett.78, 2220 (1997) Weakly-coupled qubits Quasiparticle pole Three quasiparticle continuum ~3D Structure holds to all orders in 1/g

  11. Lowest excited states: domain walls Coupling between qubits creates new “domain-wall” quasiparticle states at momentum p p Strongly-coupled qubits Ground states:

  12. S. Sachdev and A.P. Young, Phys. Rev. Lett.78, 2220 (1997) Strongly-coupled qubits Two domain-wall continuum ~2D Structure holds to all orders in g

  13. “Flipped-spin” Quasiparticle weight Z A.V. Chubukov, S. Sachdev, and J.Ye, Phys. Rev. B 49, 11919 (1994) g gc Ferromagnetic moment N0 P. Pfeuty Annals of Physics, 57, 79 (1970) g gc Excitation energy gap D g gc Entangled states at g of order unity

  14. Critical coupling No quasiparticles --- dissipative critical continuum

  15. Quasiclassical dynamics Quasiclassical dynamics P. Pfeuty Annals of Physics, 57, 79 (1970) S. Sachdev and J. Ye, Phys. Rev. Lett. 69, 2411 (1992). S. Sachdev and A.P. Young, Phys. Rev. Lett. 78, 2220 (1997).

  16. Outline • Quantum Ising Chain • Landau-Ginzburg-Wilson theory Mean field theory and the evolution of the excitation spectrum. • Superfluid-insulator transition Boson Hubbard model at integer filling. • Tilting the Mott insulator Density wave order at an Ising transition. • Bosons at fractional filling Beyond the Landau-Ginzburg-Wilson paradigm.

  17. II. Landau-Ginzburg-Wilson theory Mean field theory and the evolution of the excitation spectrum

  18. Outline • Quantum Ising Chain • Landau-Ginzburg-Wilson theory Mean field theory and the evolution of the excitation spectrum. • Superfluid-insulator transition Boson Hubbard model at integer filling. • Tilting the Mott insulator Density wave order at an Ising transition. • Bosons at fractional filling Beyond the Landau-Ginzburg-Wilson paradigm.

  19. III. Superfluid-insulator transition Boson Hubbard model at integer filling

  20. Bosons at density f = 1 Weak interactions: superfluidity Strong interactions: Mott insulator which preserves all lattice symmetries LGW theory: continuous quantum transitions between these states M. Greiner, O. Mandel, T. Esslinger, T. W. Hänsch, and I. Bloch, Nature415, 39 (2002).

  21. I. The Superfluid-Insulator transition For small U/t, ground state is a superfluid BEC with superfluid density density of bosons Boson Hubbard model M.PA. Fisher, P.B. Weichmann, G. Grinstein, and D.S. Fisher Phys. Rev. B40, 546 (1989).

  22. What is the ground state for large U/t ? Typically, the ground state remains a superfluid, but with superfluid density density of bosons The superfluid density evolves smoothly from large values at small U/t, to small values at large U/t, and there is no quantum phase transition at any intermediate value of U/t. (In systems with Galilean invariance and at zero temperature, superfluid density=density of bosons always, independent of the strength of the interactions)

  23. Ground state has “density wave” order, which spontaneously breaks lattice symmetries What is the ground state for large U/t ? Incompressible, insulating ground states, with zero superfluid density, appear at special commensurate densities

  24. Excitations of the insulator: infinitely long-lived, finite energy quasiparticles and quasiholes

  25. Excitations of the insulator: infinitely long-lived, finite energy quasiparticles and quasiholes

  26. Excitations of the insulator: infinitely long-lived, finite energy quasiparticles and quasiholes

  27. Quasiparticle pole ~3D Insulating ground state Continuum of two quasiparticles + one quasihole Similar result for quasi-hole excitations obtained by removing a boson

  28. Quasiparticle weight Z g gc Superfluid density rs g gc Excitation energy gap D g Entangled states at of order unity A.V. Chubukov, S. Sachdev, and J.Ye, Phys. Rev. B 49, 11919 (1994) gc

  29. Crossovers at nonzero temperature Quasiclassical dynamics Quasiclassical dynamics M.P.A. Fisher, G. Girvin, and G. Grinstein, Phys. Rev. Lett.64, 587 (1990). K. Damle and S. Sachdev Phys. Rev. B 56, 8714 (1997). S. Sachdev and J. Ye, Phys. Rev. Lett. 69, 2411 (1992). K. Damle and S. Sachdev Phys. Rev. B 56, 8714 (1997).

  30. Outline • Quantum Ising Chain • Landau-Ginzburg-Wilson theory Mean field theory and the evolution of the excitation spectrum. • Superfluid-insulator transition Boson Hubbard model at integer filling. • Tilting the Mott insulator Density wave order at an Ising transition. • Bosons at fractional filling Beyond the Landau-Ginzburg-Wilson paradigm.

  31. IV. Tilting the Mott insulator Density wave order at an Ising transition

  32. Applying an “electric” field to the Mott insulator

  33. What is the quantum state here ? V0=10 Erecoiltperturb= 2 ms V0= 13 Erecoiltperturb= 4 ms V0= 16 Erecoiltperturb= 9 ms V0= 20 Erecoiltperturb= 20 ms

  34. Describe spectrum in subspace of states resonantly coupled to the Mott insulator S. Sachdev, K. Sengupta, and S.M. Girvin, Physical Review B 66, 075128 (2002)

  35. Important neutral excitations (in one dimension)

  36. Nearest neighbor dipole Important neutral excitations (in one dimension)

  37. Creating dipoles on nearest neighbor links creates a state with relative energy U-2E ; such states are not part of the resonant manifold Important neutral excitations (in one dimension)

  38. Nearest neighbor dipole Important neutral excitations (in one dimension)

  39. Nearest-neighbor dipoles Dipoles can appear resonantly on non-nearest-neighbor links. Within resonant manifold, dipoles have infinite on-link and nearest-link repulsion Important neutral excitations (in one dimension)

  40. Charged excitations (in one dimension) Effective Hamiltonian for a quasiparticle in one dimension (similar for a quasihole): All charged excitations are strongly localized in the plane perpendicular electric field. Wavefunction is periodic in time, with period h/E (Bloch oscillations) Quasiparticles and quasiholes are not accelerated out to infinity

  41. A non-dipole state State has energy 3(U-E) but is connected to resonant state by a matrix element smaller than t2/U State is not part of resonant manifold

  42. Hamiltonian for resonant dipole states (in one dimension) Determine phase diagram of Hd as a function of (U-E)/t Note: there is no explicit dipole hopping term. However, dipole hopping is generated by the interplay of terms in Hd and the constraints.

  43. Weak electric fields: (U-E) t Ground state is dipole vacuum (Mott insulator) First excited levels: single dipole states t t Effective hopping between dipole states t t If both processes are permitted, they exactly cancel each other. The top processes is blocked when are nearest neighbors

  44. Strong electric fields: (E-U) t Ground state has maximal dipole number. Two-fold degeneracy associated with Ising density wave order: Eigenvalues (U-E)/t

  45. Ising quantum critical point at E-U=1.08 t Equal-time structure factor for Ising order parameter (U-E)/t S. Sachdev, K. Sengupta, and S.M. Girvin, Physical Review B 66, 075128 (2002)

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