Strongly interacting cold atoms Subir Sachdev Talks online at

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Presentation transcript:

Strongly interacting cold atoms Subir Sachdev Talks online at

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

Fermions with repulsive interactions Density

Fermions with repulsive interactions Characteristics of this ‘trivial’ quantum critical point: Zero density critical point allows an elegant connection between few body and many body physics. No “order parameter”. “Topological” characterization in the existence of the Fermi surface in one state. No transition at T > 0. Characteristic crossovers at T > 0, between quantum criticality, and low T regimes.

Fermions with repulsive interactions Characteristics of this ‘trivial’ quantum critical point: T Quantum critical: Particle spacing ~ de Broglie wavelength Classical Boltzmann gas Fermi liquid

Fermions with repulsive interactions Characteristics of this ‘trivial’ quantum critical point: d < 2 d > 2 d > 2 – interactions are irrelevant. Critical theory is the spinful free Fermi gas. d < 2 – universal fixed point interactions. In d=1 critical theory is the spinless free Fermi gas (Tonks gas). u u Tonks gas

Bosons with repulsive interactions d < 2 d > 2 Critical theory in d =1 is also the spinless free Fermi gas (Tonks gas). The dilute Bose gas in d >2 is controlled by the zero-coupling fixed point. Interactions are “dangerously irrelevant” and the density above onset depends upon bare interaction strength (Yang-Lee theory). Density u u Tonks gas

Fermions with attractive interactions d > 2 Universal fixed-point is accessed by fine-tuning to a Feshbach resonance. Density onset transition is described by free fermions for weak- coupling, and by (nearly) free bosons for strong coupling. The quantum-critical point between these behaviors is the Feshbach resonance. Weak-coupling BCS theory BEC of paired bound state P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007). -u Feshbach resonance

Fermions with attractive interactions detuning P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007).

Fermions with attractive interactions detuning Free fermions P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007).

Fermions with attractive interactions detuning Free fermions P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007). “Free” bosons

Fermions with attractive interactions detuning P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007). Universal theory of gapless bosons and fermions, with decay of boson into 2 fermions relevant for d < 4

Fermions with attractive interactions detuning P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007). Quantum critical point at  =0, =0, forms the basis of the theory of the BEC-BCS crossover, including the transitions to FFLO and normal states with unbalanced densities

D. E. Sheehy and L. Radzihovsky, Phys. Rev. Lett. 95, (2005) Fermions with attractive interactions Universal phase diagram

Fermions with attractive interactions Universal phase diagram P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007). h – Zeeman field

D. E. Sheehy and L. Radzihovsky, Phys. Rev. Lett. 95, (2005) Fermions with attractive interactions Universal phase diagram

D. E. Sheehy and L. Radzihovsky, Phys. Rev. Lett. 95, (2005) Fermions with attractive interactions Universal phase diagram

Expansion in  =4-d Y. Nishida and D.T. Son, Phys. Rev. Lett. 97, (2006) Quantum Monte Carlo J. Carlon, S.-Y. Chang, V.R. Pandharipande, and K.E. Schmidt, Phys. Rev. Lett. 91, (2003). Fermions with attractive interactions Ground state properties at unitarity and balanced density Expansion in 1/N with Sp(2N) symmetry M. Y. Veillette, D. E. Sheehy, and L. Radzihovsky Phys. Rev. A 75, (2007)

Expansion in 1/N with Sp(2N) symmetry M. Y. Veillette, D. E. Sheehy, and L. Radzihovsky Phys. Rev. A 75, (2007) Fermions with attractive interactions Ground state properties near unitarity and balanced density Quantum Monte Carlo J. Carlon, S.-Y. Chang, V.R. Pandharipande, and K.E. Schmidt, Phys. Rev. Lett. 91, (2003).

E. Burovski, N. Prokof’ev, B. Svistunov, and M. Troyer, New J. Phys. 8, 153 (2006) Fermions with attractive interactions Finite temperature properties at unitarity and balanced density Expansion in 1/N with Sp(2N) symmetry M. Y. Veillette, D. E. Sheehy, and L. Radzihovsky Phys. Rev. A 75, (2007) P. Nikolic and S. Sachdev, Phys. Rev. A 75, (2007).

V. Gurarie, L. Radzihovsky, and A.V. Andreev, Phys. Rev. Lett. 94, (2005) C.-H. Cheng and S.-K. Yip, Phys. Rev. Lett. 95, (2005) Fermions with attractive interactions in p-wave channel

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

M. Greiner, O. Mandel, T. Esslinger, T. W. Hänsch, and I. Bloch, Nature 415, 39 (2002).

Velocity distribution of 87 Rb atoms Superfliud

M. Greiner, O. Mandel, T. Esslinger, T. W. Hänsch, and I. Bloch, Nature 415, 39 (2002). Velocity distribution of 87 Rb atoms Insulator

1st order coherence disappears in the Mott-insulating state. Noise correlation function oscillates at reciprocal lattice vectors; bunching effect of bosons. Noise correlation (time of flight) in Mott-insulators Folling et al., Nature 434, 481 (2005); Altman et al., PRA 70, (2004).

Two dimensional superfluid-Mott insulator transition I. B. Spielman et al., cond-mat/

Fermionic atoms in optical lattices Observation of Fermi surface. Low density: metal high density: band insulator Esslinger et al., PRL 94:80403 (2005) Fermions with near-unitary interactions in the presence of a periodic potential

E.G. Moon, P. Nikolic, and S. Sachdev, to appear

Universal phase diagram of fermions with near-unitary interactions in the presence of a periodic potential E.G. Moon, P. Nikolic, and S. Sachdev, to appear Expansion in 1/N with Sp(2N) symmetry

E.G. Moon, P. Nikolic, and S. Sachdev, to appear Boundaries to insulating phases for different values of a L where is the detuning from the resonance Universal phase diagram of fermions with near-unitary interactions in the presence of a periodic potential

E.G. Moon, P. Nikolic, and S. Sachdev, to appear Boundaries to insulating phases for different values of a L where is the detuning from the resonance Insulators have multiple band-occupancy, and are intermediate between band insulators of fermions and Mott insulators of bosonic fermion pairs Universal phase diagram of fermions with near-unitary interactions in the presence of a periodic potential

Artificial graphene in optical lattices Band Hamiltonian (  -bonding) for spin- polarized fermions. A B B B Congjun Wu et al

Flat bands in the entire Brillouin zone Flat band + Dirac cone. localized eigenstates. Many correlated phases possible

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

M. Greiner, O. Mandel, T. Esslinger, T. W. Hänsch, and I. Bloch, Nature 415, 39 (2002).

Superfluid Insulator Non-zero temperature phase diagram Depth of periodic potential

Superfluid Insulator Non-zero temperature phase diagram Depth of periodic potential Dynamics of the classical Gross-Pitaevski equation

Superfluid Insulator Non-zero temperature phase diagram Depth of periodic potential Dilute Boltzmann gas of particle and holes

Superfluid Insulator Non-zero temperature phase diagram Depth of periodic potential No wave or quasiparticle description

D. B. Haviland, Y. Liu, and A. M. Goldman, Phys. Rev. Lett. 62, 2180 (1989) Resistivity of Bi films M. P. A. Fisher, Phys. Rev. Lett. 65, 923 (1990)

Superfluid Insulator Non-zero temperature phase diagram Depth of periodic potential

Superfluid Insulator Non-zero temperature phase diagram Depth of periodic potential Collisionless-to hydrodynamic crossover of a conformal field theory (CFT) K. Damle and S. Sachdev, Phys. Rev. B 56, 8714 (1997).

Superfluid Insulator Non-zero temperature phase diagram Depth of periodic potential Collisionless-to hydrodynamic crossover of a conformal field theory (CFT) K. Damle and S. Sachdev, Phys. Rev. B 56, 8714 (1997). Needed: Cold atom experiments in this regime

Hydrodynamics of a conformal field theory (CFT) Maldacena’s AdS/CFT correspondence relates the hydrodynamics of CFTs to the quantum gravity theory of the horizon of a black hole in Anti-de Sitter space.

Holographic representation of black hole physics in a 2+1 dimensional CFT at a temperature equal to the Hawking temperature of the black hole. Black hole 3+1 dimensional AdS space Hydrodynamics of a conformal field theory (CFT)

Hydrodynamics of a CFT Waves of gauge fields in a curved background

Hydrodynamics of a conformal field theory (CFT) The scattering cross-section of the thermal excitations is universal and so transport co- efficients are universally determined by k B T Charge diffusion constant Conductivity K. Damle and S. Sachdev, Phys. Rev. B 56, 8714 (1997).

Hydrodynamics of a conformal field theory (CFT) P. Kovtun, C. Herzog, S. Sachdev, and D.T. Son, hep-th/ Spin diffusion constant Spin conductivity For the (unique) CFT with a SU(N) gauge field and 16 supercharges, we know the exact diffusion constant associated with a global SO(8) symmetry:

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

Outline 1.Quantum liquids near unitarity: from few-body to many-body physics (a) Tonks gas in one dimension (b) Paired fermions across a Feshbach resonance 2.Optical lattices (a) Superfluid-insulator transition (b) Quantum-critical hydrodynamics via mapping to quantum theory of black holes. (c) Entanglement of valence bonds Strongly interacting cold atoms

H.P. Büchler, M. Hermele, S.D. Huber, M.P.A. Fisher, and P. Zoller, Phys. Rev. Lett. 95, (2005) Ring-exchange interactions in an optical lattice using a Raman transition

Antiferromagnetic (Neel) order in the insulator

Induce formation of valence bonds by e.g. ring-exchange interactions A. W. Sandvik, cond-mat/

=

=

=

=

=

= Entangled liquid of valence bonds (Resonating valence bonds – RVB) P. Fazekas and P.W. Anderson, Phil Mag 30, 23 (1974).

= N. Read and S. Sachdev, Phys. Rev. Lett. 62, 1694 (1989). R. Moessner and S. L. Sondhi, Phys. Rev. B 63, (2001). Valence bond solid (VBS)

= N. Read and S. Sachdev, Phys. Rev. Lett. 62, 1694 (1989). R. Moessner and S. L. Sondhi, Phys. Rev. B 63, (2001). Valence bond solid (VBS)

= Excitations of the RVB liquid

=

=

=

= Electron fractionalization: Excitations carry spin S=1/2 but no charge

= Excitations of the VBS

=

=

=

= Free spins are unable to move apart: no fractionalization, but confinement

Phase diagram of square lattice antiferromagnet A. W. Sandvik, cond-mat/

Phase diagram of square lattice antiferromagnet VBS order K/J Neel order T. Senthil, A. Vishwanath, L. Balents, S. Sachdev and M.P.A. Fisher, Science 303, 1490 (2004).

Phase diagram of square lattice antiferromagnet VBS order K/J Neel order T. Senthil, A. Vishwanath, L. Balents, S. Sachdev and M.P.A. Fisher, Science 303, 1490 (2004). RVB physics appears at the quantum critical point which has fractionalized excitations: “deconfined criticality”

Temperature, T 0 Quantum criticality of fractionalized excitations K/J

Phases of nuclear matter

Rapid progress in the understanding of quantum liquids near unitarity Rich possibilities of exotic quantum phases in optical lattices Cold atom studies of the entanglement of large numbers of qubits: insights may be important for quantum cryptography and quantum computing. Tabletop “laboratories for the entire universe”: quantum mechanics of black holes, quark-gluon plasma, neutrons stars, and big-bang physics. Conclusions