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Phenomenology of Supersolids

Phenomenology of Supersolids. Alan Dorsey & Chi-Deuk Yoo Department of Physics University of Florida Paul Goldbart Department of Physics University of Illinois at Urbana-Champaign John Toner Department of Physics University of Oregon.

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Phenomenology of Supersolids

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  1. Phenomenology of Supersolids Alan Dorsey & Chi-Deuk YooDepartment of Physics University of Florida Paul GoldbartDepartment of Physics University of Illinois at Urbana-Champaign John TonerDepartment of Physics University of Oregon A. T. Dorsey, P. M. Goldbart, and J. Toner, “Squeezing superfluid from a stone: Coupling superfluidity and elasticity in a supersolid,” Phys. Rev. Lett. 96, 055301 (2006). C.-D. Yoo and A. T. Dorsey, work in progress.

  2. Outline • Phenomenology-what can we learn without a microscopic model? • Landau theory of the normal solid to supersolid transition: coupling superfluidity to elasticity. Assumptions: • Normal to supersolid transition is continuous (2nd order). • Supersolid order parameter is a complex scalar (just like the superfluid phase). • What is the effect of the elasticity on the transition? • Hydrodynamics of a supersolid: • Employ conservation laws and symmetries to deduce the long-lived hydrodynamic modes. • Mode counting: additional collective mode in the supersolid phase. • Use linearized hydrodynamics to calculate S(q,w) .

  3. Landau theory for a superfluid • Symmetry of order parameter • Broken U(1) symmetry for T<Tc. • Coarse-grained free energy: • Average over configurations: • Fluctuations shift T0! TC, produce singularities as a function of the reduced temperature t=|(T-Tc)/Tc| . • Universal exponents and amplitude ratios.

  4. Specific heat near the l transition • The singular part of the specific heat is a correlation function: • For the l transition, a= -0.0127. Lipa et al., Phys. Rev. B (2003). Barmatz & Rudnick, Phys. Rev. (1968)

  5. Sound speed • What if we allow for local density fluctuations dr in the fluid, with a bare bulk modulus B0? The coarse-grained free energy is now • The “renormalized” bulk modulus B is then • The sound speed acquires the specific heat singularity (Pippard-Buckingham-Fairbank):

  6. Coupling superfluidity & elasticity • Structured (rigid) superfluid: need anisotropic gradient terms: • Elastic energy: Hooke’s law. 5 independent elastic constants for an hcp lattice: • Compressible lattice: couple strain to the order parameter, obtain a strain dependent Tc. • Minimal model for the normal to supersolid transition:

  7. Related systems • Analog: XY ferromagnet on a compressible lattice. Exchange coupling will depend upon the local dilation of the lattice. • Studied extensively: Fisher (1968), Larkin & Pikin (1969), De Moura, Lubensky, Imry & Aharony (1976), Bergman & Halperin (1976), … • Under some conditions the elastic coupling can produce a first order transition. • Other systems: • Charge density waves: Aronowitz, Goldbart, & Mozurkewich (1990). • Spin density waves: M. Walker (1990s). • A15 superconductors: L.R. Testardi (1970s).

  8. Universality of the transition • De Moura, Lubensky, Imry & Aharony (1976): elastic coupling doesn’t effect the universality class of the transition if the specific heat exponent of the rigid system is negative,which it is for the 3D XY model. The critical behavior for the supersolid transition is in the 3D XY universality class. • But coupling does matter for the elastic constants: • Could be detected in a sound speed experiment as a dip in the sound speed. • Anomaly appears in the “longitudinal” sound in a single crystal. Should appear in both longitudinal and transverse sound in polycrystalline samples.

  9. Specific heat Specific heat near the putative supersolid transition in solid 4He. High resolution specific heat measurements of the lambda transition in zero gravity. J.A. Lipa et al., Phys. Rev. B 68, 174518 (2003). Lin, Clark, and Chan, PSU preprint (2007)

  10. Inhomogeneous strains • Inhomogeneous strains result in a local Tc. The local variations in Tc will broaden the transition. • Could “smear away” any anomalies in the specific heat. • Strains could be due to geometry, dislocations, grain boundaries, etc. • Question: could defects induce supersolidity?

  11. Supersolidity from dislocations? • Dislocations can promote superfluidity (John Toner). Recall model: • Quenched dislocations produce large, long-ranged strains. For an edge dislocation (isotropic elasticity) • For a screw dislocation, • Even if t0>0 (QMC), can have t<0 near the dislocation! Edge dislocation Screw dislocation

  12. Condensation on edge dislocation • Euler-Lagrange equation: • To find Tc solve linearized problem; looks like Schrodinger equation: • For the edge dislocation, • Need to find the spectrum of a d=2 dipole potential. • Expand the free energy

  13. Details: Quantum dipole problem • Instabililty first occurs for the ground state: • Variational estimate: • Edge dislocations always increase the transition temperature! • What about screw dislocations? Either nonlinear strains coupling to |y|2 or linear strain coupling to gradients of y [E. M. Chudnovsky, PRB 64, 212503 (2001)]. • J. Toner: properties of a network of such superfluid dislocations (unpublished).

  14. Interesting references V.M. Nabutovskii and V.Ya. Shapiro, Sov. Phys. JETP 48, 480 (1979).

  15. Hydrodynamics I: simple fluid • Conservation laws and broken symmetries lead to long-lived “hydrodynamic” modes (lifetime diverges at long wavelengths). • Simple fluid: • Conserved quantities are r, gi, e. • No broken symmetries. • 5 conserved densities) 5 hydrodynamic modes. • 2 transverse momentum diffusion modes . • 1 longitudinal thermal diffusion mode . • 2 longitudinal sound modes .

  16. Light scattering from a simple fluid Rayleigh peak (thermal diffusion) • Intensity of scattered light: • Longitudinal modes couple to density fluctuations. • Sound produces the Brillouin peaks. • Thermal diffusion produces the Rayleigh peak (coupling of thermal fluctuations to the density through thermal expansion). Brillouin peak (adiabatic sound) P. A. Fleury and J. P. Boon, Phys. Rev. 186, 244 (1969)

  17. Hydrodynamics II: superfluid • Conserved densities r, gi, e . • Broken U(1) gauge symmetry • Another equation of motion: • 6 hydrodynamic modes: • 2 transverse momentum diffusion modes. • 2 longitudinal (first) sound modes. • 2 longitudinal second sound modes. • Central Rayleigh peak splits into two new Brillouin peaks.

  18. Light scattering in a superfluid Winterling, Holmes & Greytak PRL 1973 Tarvin, Vidal & Greytak 1977

  19. Solid “hydrodynamics” • Conserved quantities: r, gi, e . • Broken translation symmetry: ui, i=1,2,3 • Mode counting: 5 conserved densities and 3 broken symmetry variables) 8 hydrodynamic modes. For an isotropic solid (two Lame constants l and m): • 2 pairs of transverse sound modes (4), • 1 pair of longitudinal sound modes (2), • 1 thermal diffusion mode (1). • What’s missing? Martin, Parodi, and Pershan (1972): diffusion of vacancies and interstitials.

  20. Vacancies and interstitials • Local density changes arise from either lattice fluctuations (with a displacement field u) or vacancies and interstitials. • In classical solids the density of vacancies is small at low temperatures. • Does 4He have zero point vacancies?

  21. Supersolid hydrodynamics • Conserved quantities: r, gi, e • Broken symmetries: ui, gauge symmetry. • Mode counting: 5 conserved densities and 4 broken symmetry variables) 9 hydrodynamic modes. • 2 pairs of transverse sound modes (4). • 1 pair of longitudinal sound modes (2). • 1 pair of longitudinal “fourth sound” modes (2). • 1 longitudinal thermal diffusion mode. • Use Andreev & Lifshitz hydrodynamics to derive the structure function (isothermal, isotropic solid). New Brillouin peaks below Tc.

  22. Structure function for supersolid Second sound First sound

  23. Supersolid Lagrangian • Lagrangian • Reversible dynamics for the phase and lattice displacement fields • Lagrangian coordinates Ri, Eulerian coordinates xi, deformation tensor • Respect symmetries (conservation laws): rotational symmetry, Galilean invariance, gauge symmetry. • Reproduces Andreev-Lifshitz hydrodynamics. Agrees with recent work by Son (2005) [disagrees with Josserand (2007), Ye (2007)]. • Good starting point for studying vortex dynamics in supersolids (Yoo and Dorsey, unpublished). Question: do vortices in supersolids behave differently than in superfluids?

  24. Summary • Landau theory of the normal solid to supersolid transition. Coupling to the elastic degrees of freedom doesn’t change the critical behavior. • Predicted anomalies in the elastic constants that should be observable in sound speed measurements. • Noted the importance of inhomogeneous strains in rounding the transition. • Structure function of a model supersolid using linearized hydrodynamics. A new collective mode emerges in the supersolid phase, which might be observable in light scattering. • In progress: • Lagrangian formulation of the hydrodynamics. • Vortex and dislocation dynamics in a supersolid.

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