Your search keyword '"Hur, Karyn Le"' showing total 10 results

1. Chiral Mott insulators, Meissner effect, and Laughlin states in quantum ladders.

Author

Petrescu, Alexandra and Hur, Karyn Le

Subjects

*CHIRALITY of nuclear particles, *MAGNETIC fields, *MEISSNER effect, *SUPERFLUIDITY, *SUPERCONDUCTIVITY

Abstract

We introduce generic bosonic models exemplifying that chiral Meissner currents can persist in insulating phases of matter. We first consider interacting bosons on a two-leg ladder. The total density sector can be gapped in a bosonic Mott insulator at odd-integer Tiling, while the relative density sector remains superfluid due to interchain hopping. Coupling the relative density to gauge fields yields a pseudospin Meissner effect. We show that the same phase arises if the bosons are replaced by spinful fermions confined in Cooper pairs, and find a dual fermionic Mott insulator with spinon currents. We prove that, by tuning the mean density, the Mott insulator with Meissner currents turns into a low-dimensional bosonic v = 1/2 Laughlin state for strong enough repulsive interactions across the ladder rungs. We finally discuss extensions to multileg ladders and bilayers in which spinon superfluids with Meissner currents become possible. We propose two experimental realizations, one with ultracold atoms in the setup of Atala et al. [Nat. Phys. 10, 588 (2014)] and another with Josephson junction arrays. We also address a Bose-Fermi mixture subject to a magnetic Held in connection with the pseudogap phase of high- Tc cuprates. [ABSTRACT FROM AUTHOR]

Published

2015

2. Strongly correlated thermoelectric transport beyond linear response.

Author

Dutt, Prasenjit and Hur, Karyn Le

Subjects

*THERMOELECTRIC effects, *STEADY-state flow, *QUANTUM theory, *ELECTRON paramagnetic resonance, *MEAN field theory

Abstract

We investigate nonlinear thermoelectric transport through quantum impurity systems with strong on-site interactions. We show that the steady-state transport through interacting quantum impurities in contact with electron reservoirs at significantly different temperatures can be captured by an effective-equilibrium density matrix, expressed compactly in terms of the Lippmann-Schwinger operators of the system. In addition, the reservoirs can be maintained at arbitrary chemical potentials. The interplay between the temperature gradient and bias voltage gives rise to a nontrivial breaking of particle-hole symmetry in the strongly correlated regime, manifest in the Abrikosov-Suhl localized electron resonance. This purely many-body effect, which is in agreement with experimental results, is beyond the purview of mean-field arguments. [ABSTRACT FROM AUTHOR]

Published

2013

3. Bosonic Mott Insulator with Meissner Currents.

Author

Pelrescu, Alexandra and Hur, Karyn Le

Subjects

*BOSONS, *MEISSNER effect, *LATTICE dynamics, *CURRENT density (Electromagnetism), *SUPERFLUIDITY, *PHASE diagrams, *DENSITY wave theory, *JOSEPHSON junctions

Abstract

We introduce a generic bosonic model exemplifying that (spin) Meissner currents can persist in insulating phases of matter. We consider two species of interacting bosons on a lattice. Our model exhibits separation of charge (total density) and spin (relative density): the charge sector is gapped in a bosonic Mott insulator phase with total density one, while the spin sector remains superfluid due to interspecies conversion. Coupling the spin sector to the gauge fields yields a spin Meissner effect reflecting the long-range spin superfluid coherence. We investigate the resulting phase diagram and describe other possible spin phases of matter in the Mott regime possessing chiral currents as well as a spin-density wave phase. The model presented here is realizable in Josephson junction arrays and in cold atom experiments. [ABSTRACT FROM AUTHOR]

Published

2013

4. Bosonic Mott Insulator with Meissner Currents.

Author

Pelrescu, Alexandra and Hur, Karyn Le

Subjects

*MEISSNER effect, *MATTER, *BOSONS, *COUPLING constants, *SUPERFLUIDITY, *COHERENCE (Nuclear physics)

Abstract

The authors showcase that in a generic bosonic model Meissner currents can persist in insulated phases of matter. The authors mention about interaction of bosons in a lattice which exhibit separation of charge and spin with charge in a bosonic Mott insulator phase of total density one while spin in superfluid state. The authors then coupled the spin sector to gauge fields that resulted in spin Meissner effect reflecting long-range superfluid coherence.

Published

2013

5. Kondo resonance of a microwave photon.

Author

Hur, Karyn Le

Subjects

*QUANTUM optics, *RESONANCE, *PHOTONS, *HAMILTONIAN systems, *ELECTRIC lines, *QUANTUM theory

Abstract

We emulate renormalization group models, such as the spin-boson Hamiltonian or the anisotropic Kondo model, from a quantum optics perspective by considering a superconducting device. The infrared confinement involves photon excitations of two tunable transmission lines entangled to an artificial spin-1/2 particle or double-island charge qubit. Focusing on the propagation of microwave light, in the underdamped regime of the spin-boson model, we identify a many-body resonance where a photon is absorbed at the renormalized qubit frequency and reemitted forward in an elastic manner. We also show that asymptotic freedom of microwave light is reached by increasing the input signal amplitude at low temperatures, which allows the disappearance of the transmission peak. [ABSTRACT FROM AUTHOR]

Published

2012

6. Anisotropic quantum spin Hall effect, spin-orbital textures, and the Mott transition.

Author

Liu, Tianhan, Doucot, Benoit, and Hur, Karyn Le

Subjects

*HALL effect, *SPIN-orbit interactions, *METAL-insulator transitions, *QUANTUM theory, *INVARIANTS (Mathematics)

Abstract

We investigate the interplay between topological effects and Mott physics in two dimensions on a graphenelike lattice, via a tight-binding model containing an anisotropic spin-orbit coupling on the next-nearest-neighbor links and the Hubbard interaction. We thoroughly analyze the resulting phases, namely, a topological band insulator phase or anisotropic quantum spin Hall phase until moderate-strength interactions and a Neel and a spiral phase at large interactions in the Mott regime, as well as the formation of a spin-orbital texture in the bulk at the Mott transition. The emergent magnetic orders at large interactions are analyzed through a spin-wave analysis and mathematical arguments. At weak interactions, by analogy with the Kane-Mele model, the system is described through a Z2 topological invariant. In addition, we describe how the anisotropic spin-orbit coupling already produces an exotic spin texture at the edges. The physics at the Mott transition is described in terms of a U(1) slave-rotor theory. Taking into account gauge fluctuations around the mean-field saddle-point solution, we show how the spin texture now proliferates into the bulk above the Mott critical point. The latter emerges from the response of the spinons under the insertion of monopoles and this becomes more pronounced as the spin-orbit coupling becomes prevalent. We discuss implications of our predictions for thin films of the iridate compound Na2IrO3 and also graphenelike systems. [ABSTRACT FROM AUTHOR]

Published

2013

7. Anomalous Hall effects of light and chiral edge modes on the Kagome lattice.

Author

Petrescu, Alexandra, Houck, Andrew A., and Hur, Karyn Le

Subjects

*HALL effect, *LATTICE dynamics, *GAUGE field theory, *BOLTZMANN'S equation, *MAGNETIC fields

Abstract

We theoretically investigate a photonic Kagome lattice which can be realized in microwave cavity arrays using current technology. The Kagome lattice exhibits an exotic band structure with three bands, one of which can be made completely flat. The presence of artificial gauge fields makes it possible to emulate topological phases and induce chiral edge modes which can coexist inside the energy gap with the flat band that is topologically trivial. By tuning the artificial fluxes or in the presence of disorder, the flat band can also acquire a bandwidth in energy allowing the coexistence between chiral edge modes and bulk extended states; in this case the chiral modes become fragile towards scattering into the bulk. The photonic system then exhibits equivalents of both a quantum Hall effect without Landau levels and an anomalous Hall effect characterized by a nonquantized Ghern number. We discuss experimental observables such as local density of states and edge currents. We show how synthetic uniform magnetic fields can be engineered, which allows an experimental probe of Landau levels in the photonic Kagome lattice. We then draw on semiclassical Boltzmann equations for transport to devise a method to measure Berry's phases around loops in the Brillouin zone. The method is based solely on wave-packet interference and can be used to determine band Chern numbers or the photonic equivalent of the anomalous Hall response. We demonstrate the robustness of these measurements towards on-site and gauge-field disorder. We also show the stability of the anomalous quantum Hall phase for nonlinear cavities and for (artificial) atom-photon interactions. [ABSTRACT FROM AUTHOR]

Published

2012

8. Heisenberg uncertaint y principle as a probe of entanglement entropy: Application to superradiant quantum phase transitions.

Author

Nataf, Pierre, Dogan, Mehmet, and Hur, Karyn Le

Subjects

*UNCERTAINTY (Information theory), *QUANTUM entanglement, *ENTROPY, *SUPERRADIANCE, *QUANTUM phase transitions, *SENSITIVITY analysis, *THERMODYNAMICS, *CRITICAL point (Thermodynamics)

Abstract

Quantum phase transitions are often embodied by the critical behavior of purely quantum quantities such as entanglement or quantum fluctuations. In critical regions, we underline a general scaling relation between the entanglement entropy and one of the most fundamental and simplest measure of the quantum fluctuations, the Heisenberg uncertainty principle. Then, we show that the latter represents a sensitive probe of superradiant quantum phase transitions in standard models of photons such as the Dicke Hamiltonian, which embodies an ensemble of two-level systems interacting with one quadrature of a single and uniform bosonic field. We derive exact results in the thermodynamic limit and for a finite number Ν of two-level systems: as a reminiscence of the entanglement properties between light and the two-level systems, the product ΔxΔp diverges at the quantum critical point as N1/6. We generalize our results to the double quadrature Dicke model where the two quadratures of the bosonic field are now coupled to two independent sets of two-level systems. Our findings, which show that the entanglement properties between light and matter can be accessed through the Heisenberg uncertainty principle, can be tested using Bose-Einstein condensates in optical cavities and circuit quantum electrodynamics. [ABSTRACT FROM AUTHOR]

Published

2012

9. Realizing topological Mott insulators from the RKKY interaction.

Author

Tianhan Liu, Douçot, Benoît, and Hur, Karyn Le

Subjects

*ELECTRIC insulators & insulation, *FERMIONS, *SPIN-orbit interactions

Abstract

We engineer topological insulating phases in a fermion-fermion mixture on the honeycomb lattice, without resorting to artificial gauge fields or spin-orbit couplings and considering only local interactions. Essentially, upon integrating out the fast component (characterized by a larger hopping amplitude) in a finite region of dopings, we obtain an effective interaction between the slow fermions at half-filling, which acquires a Haldane mass with opposite parity in the two valleys of the Dirac cones, thus triggering a quantum anomalous Hall effect. We carefully analyze the competition between the induced Semenoff-type mass (producing charge density wave orders in real space) versus the Haldane mass (quantum anomalous Hall phase), as a function of the chemical potential of the fast fermions. If the second species involves spin-1/2 particles, this interaction may induce a quantum spin Hall phase. Such fermion-fermion mixtures can be realized in optical lattices or in graphene heterostructures. [ABSTRACT FROM AUTHOR]

Published

2016

10. Detecting Quantum Critical Points Using Bipartite Fluctuations.

Author

Rachel, Stephan, Laflorencie, Nicolas, Song, H. Francis, and Hur, Karyn Le

Subjects

*QUANTUM phase transitions, *BOSONS, *ENTROPY, *NEUMANN problem, *ANTIFERROMAGNETISM, *COLD gases, *QUANTUM chromodynamics, *FLUCTUATIONS (Physics)

Abstract

We show that the concept of bipartite fluctuations F provides a very efficient tool to detect quantum phase transitions in strongly correlated systems. Using state-of-the-art numerical techniques complemented with analytical arguments, we investigate paradigmatic examples for both quantum spins and bosons. As compared to the von Neumann entanglement entropy, we observe that F allows us to find quantum critical points with much better accuracy in one dimension. We further demonstrate that F can be successfully applied to the detection of quantum criticality in higher dimensions with no prior knowledge of the universality class of the transition. Promising approaches to experimentally access fluctuations are discussed for quantum antiferromagnets and cold gases. [ABSTRACT FROM AUTHOR]

Published

2012