Your search keyword '"O'Dell, D. H. J."' showing total 18 results

1. Quantum Catastrophes and Ergodicity in the Dynamics of Bosonic Josephson Junctions.

Author

O'Dell, D. H. J.

Subjects

*QUANTUM theory, *CATASTROPHES (Mathematics), *ERGODIC theory, *BOSONS, *JOSEPHSON junctions, *CUSP forms (Mathematics), *MEAN field theory, *GROSS-Pitaevskii equations, *AIRY functions

Abstract

We study rainbow (fold) and cusp catastrophes that form in Fock space following a quench in a Bose Josephson junction. In the Gross-Pitaevskii mean-field theory, the rainbows are singular caustics, but in the second-quantized theory a Poisson resummation of the wave function shows that they are described by well-behaved Airy functions. The structural stability of these Fock space caustics against variations in the initial conditions and Hamiltonian evolution is guaranteed by catastrophe theory. We also show that the long-time dynamics are ergodic. Our results are relevant to the question posed by Berry [M. V. Berry, Nonlinearity 21, T19 (2008)]: Are there circumstances when it is necessary to second quantize wave theory in order to avoid singularities? [ABSTRACT FROM AUTHOR]

Published

2012

2. Critical exponents for an impurity in a bosonic Josephson junction: Position measurement as a phase transition.

Author

Mumford, J. and O'Dell, D. H. J.

Subjects

*JOSEPHSON junctions, *QUANTUM phase transitions, *BOSONS, *ELECTRON tunneling, *QUANTUM measurement, *IMPURITY centers

Abstract

We use fidelity susceptibility to calculate quantum critical scaling exponents for a system consisting of N identical bosons interacting with a single impurity atom in a double-well potential (bosonic Josephson junction). Above a critical value of the boson-impurity interaction energy there is a spontaneous breaking of Z2 symmetry corresponding to a second-order quantum phase transition from a balanced to an imbalanced number of particles in either the left- or the right-hand well. We show that the exponents match those in the Lipkin-Meshkov-Glick and Dicke models, suggesting that the impurity model is in the same universality class. The phase transition can be interpreted as a measurement of the position of the impurity by the bosons. [ABSTRACT FROM AUTHOR]

Published

2014

3. Bloch oscillations of cold atoms in a cavity: Effects of quantum noise.

Author

Venkatesh, B. Prasanna and O'Dell, D. H. J.

Subjects

*ATOMS, *QUANTUM noise, *OSCILLATIONS, *BLOCH spectrum, *HEISENBERG model, *SIGNAL-to-noise ratio

Abstract

We extend our theory of Bloch oscillations of cold atoms inside an optical cavity [Venkatesh et al., Phys. Rev. A 80, 063834 (2009)) to include the effects of quantum noise arising from coupling to external modes. The noise acts as a form of quantum measurement backaction by perturbing the coupled dynamics of the atoms and the light. We take it into account by solving the Heisenberg-Langevin equations for linearized fluctuations about the atomic and optical mean fields and examine how this influences the signal-to-noise ratio of a measurement of external forces using this system. In particular, we investigate the effects of changing the number of atoms, the intracavity lattice depth, and the atom-light coupling strength, and show how resonances between the Bloch oscillation dynamics and the quasiparticle spectrum have a strong influence on the signal-to-noise ratio, as well as heating effects. One of the hurdles we overcome in this paper is the proper treatment of fluctuations about time-dependent mean fields in the context of cold-atom cavity QED. [ABSTRACT FROM AUTHOR]

Published

2013

4. Balancing long-range interactions and quantum pressure: Solitons in the Hamiltonian mean-field model.

Author

Plestid, Ryan and O'Dell, D. H. J.

Subjects

*WAVE functions, *GROSS-Pitaevskii equations, *CANONICAL ensemble, *MECHANICAL models, *SOLITONS, *STATISTICAL models

Abstract

The Hamiltonian mean-field (HMF) model describes particles on a ring interacting via a cosine interaction, or equivalently, rotors coupled by infinite-range XY interactions. Conceived as a generic statistical mechanical model for long-range interactions such as gravity (of which the cosine is the first Fourier component), it has recently been used to account for self-organization in experiments on cold atoms with long-range optically mediated interactions. The significance of the HMF model lies in its ability to capture the universal effects of long-range interactions and yet be exactly solvable in the canonical ensemble. In this work we consider the quantum version of the HMF model in one dimension and provide a classification of all possible stationary solutions of its generalized Gross-Pitaevskii equation (GGPE), which is both nonlinear and nonlocal. The exact solutions are Mathieu functions that obey a nonlinear relation between the wave function and the depth of the mean-field potential, and we identify them as bright solitons. Using a Galilean transformation these solutions can be boosted to finite velocity and are increasingly localized as the mean-field potential becomes deeper. In contrast to the usual local GPE, the HMF case features a tower of solitons, each with a different number of nodes. Our results suggest that long-range interactions support solitary waves in a novel manner relative to the short-range case. [ABSTRACT FROM AUTHOR]

Published

2019

5. Parametric amplification of light in a cavity with a moving dielectric membrane: Landau-Zener problem for the Maxwell field.

Author

Hasan, F. and O'Dell, D. H. J.

Subjects

*QUANTUM theory, *LANDAU-Zener formula, *MAXWELL equations

Abstract

We perform a theoretical investigation into the classical and quantum dynamics of an optical field in a cavity containing a moving membrane ("membrane-in-the-middle" setup). Our approach is based on the Maxwell wave equation and complements previous studies based on an effective Hamiltonian. The analysis shows that for slowly moving and weakly reflective membranes the classical field dynamics can be approximated by first-order-in-time evolution given by an effective Schrödinger-type equation with a Hamiltonian that does not depend on the membrane speed. This approximate theory is the one typically adopted in cavity optomechanics and we develop a criterion for its validity. However, in more general situations, the full second-order wave equation predicts light dynamics which do not conserve energy, giving rise to parametric amplification (or attenuation) that is forbidden under first-order dynamics and can be considered to be the classical counterpart of the dynamical Casimir effect. The case of a membrane moving at constant velocity can be mapped onto the Landau-Zener problem, but with additional terms responsible for field amplification. Furthermore, the nature of the adiabatic regime is rather different from the ordinary Schrödinger case since mode amplitudes need not be constant even when there are no transitions between them. The Landau-Zener problem for a field is therefore richer than in the standard single-particle case. We use the work-energy theorem applied to the radiation pressure on the membrane as a self-consistency check for our solutions of the wave equation and as a tool to gain an intuitive understanding of energy pumped into or out of the light field by the motion of the membrane. [ABSTRACT FROM AUTHOR]

Published

2016

6. Backaction-Driven Transport of Bloch Oscillating Atoms in Ring Cavities.

Author

Goldwin, J., Venkatesh, B. Prasanna, and O'Dell, D. H. J.

Subjects

*ATOMS, *ATOMIC physics, *FORCE & energy, *MATHEMATICAL analysis, *ATOMIC interactions

Abstract

We predict that an atomic Bose-Einstein condensate strongly coupled to an intracavity optical lattice can undergo resonant tunneling and directed transport when a constant and uniform bias force is applied. The bias force induces Bloch oscillations, causing amplitude and phase modulation of the lattice which resonantly modifies the site-to-site tunneling. For the right choice of parameters a net atomic current is generated. The transport velocity can be oriented oppositely to the bias force, with its amplitude and direction controlled by the detuning between the pump laser and the cavity. The transport can also be enhanced through imbalanced pumping of the two counterpropagating running wave cavity modes. Our results add to the cold atoms quantum simulation toolbox, with implications for quantum sensing and metrology. [ABSTRACT FROM AUTHOR]

Published

2014

7. Anisotropic and Long-Range Vortex Interactions in Two-Dimensional Dipolar Bose Gases.

Author

Mulkerin, B. C., van Bijnen, R. M. W., O'Dell, D. H. J., Martin, A. M., and Parker, N. G.

Subjects

*DIPOLE-dipole interactions, *BOSE-Einstein gas, *ZWITTERIONS, *ANISOTROPY, *ANNIHILATION reactions

Abstract

We perform a theoretical study into how dipole-dipole interactions modify the properties of superfluid vortices within the context of a two-dimensional atomic Bose gas of co-oriented dipoles. The reduced density at a vortex acts like a giant antidipole, changing the density profile and generating an effective dipolar potential centred at the vortex core whose most slowly decaying terms go as 1/ρ² and ln(ρ)/ρ³. These effects modify the vortex-vortex interaction which, in particular, becomes anisotropic for dipoles polarized in the plane. Striking modifications to vortex-vortex dynamics are demonstrated, i.e., anisotropic corotation dynamics and the suppression of vortex annihilation. [ABSTRACT FROM AUTHOR]

Published

2013

8. Impurity in a bosonic Josephson junction: Swallowtail loops, chaos, self-trapping, and Dicke model.

Author

Mumford, Jesse, Larson, Jonas, and O'Dell, D. H. J.

Subjects

*JOSEPHSON junctions, *BOSONS, *CHAOS theory, *MATHEMATICAL models, *ION traps, *POTENTIAL theory (Physics), *SYMMETRY (Physics)

Abstract

We study a model describing N identical bosonic atoms trapped in a double-well potential together with a single-impurity atom, comparing and contrasting it throughout with the Dicke model. As the boson-impurity coupling strength is varied, there is a symmetry-breaking pitchfork bifurcation which is analogous to the quantum phase transition occurring in the Dicke model. Through stability analysis around the bifurcation point, we show that the critical value of the coupling strength has the same dependence on the parameters as the critical coupling value in the Dicke model. We also show that, like the Dicke model, the mean-field dynamics goes from being regular to chaotic above the bifurcation and macroscopic excitations of the bosons are observed. Although the boson-impurity system behaves like a poor man's version of the Dicke model, we demonstrate a self-trapping phenomenon which thus far has not been discussed in the realm of the Dicke model. [ABSTRACT FROM AUTHOR]

Published

2014

9. Impurity in a Bose-Einstein condensate in a double well.

Author

Mulansky, F., Mumford, J., and O'Dell, D. H. J.

Subjects

*MEAN field theory, *BOSE-Einstein condensation, *CONDENSATE oil wells, *OIL wells, *ATOMS, *BIFURCATION theory, *COHERENCE (Nuclear physics)

Abstract

We compare and contrast the mean-field and many-body properties of a Bose-Einstein condensate trapped in a double-well potential with a single impurity atom. The mean-field solutions display a rich structure of bifurcations, as parameters such as the boson-impurity interaction strength and the tilt between the two wells are varied. In particular, we study a pitchfork bifurcation in the lowest mean-field stationary solution, which occurs when the boson-impurity interaction exceeds a critical magnitude. This bifurcation, which is present for both repulsive and attractive boson-impurity interactions, corresponds to the spontaneous formation of an imbalance in the number of particles between the two wells. If the boson-impurity interaction is large, the bifurcation is associated with the onset of a Schrödinger-cat state in the many-body ground state. We calculate the coherence and number fluctuations between the two wells, and also the entanglement entropy between the bosons and the impurity. We find that the coherence can be greatly enhanced at the bifurcation. [ABSTRACT FROM AUTHOR]

Published

2011

10. Synthetic magnetohydrodynamics in Bose-Einstein condensates and routes to vortex nucleation.

Author

Taylor, L. B., van Bijnen, R. M. W., O'Dell, D. H. J., Parker, N. G., Kokkelmans, S. J. J. M. F., and Martin, A. M.

Subjects

*MAGNETOHYDRODYNAMICS, *FLUID dynamics, *BOSE-Einstein condensation, *HALL effect, *MAGNETIC fields

Abstract

Engineering of synthetic magnetic flux in Bose-Einstein condensates [ Lin et al. Nature (London) 462 628 (2009)] has prospects for attaining the high vortex densities necessary to emulate the fractional quantum Hall effect. We analytically establish the hydrodynamical behavior of a condensate in a uniform synthetic magnetic field, including its density and velocity profile. Importantly, we find that the onset of vortex nucleation observed experimentally corresponds to a dynamical instability in the hydrodynamical solutions and reveal other routes to instability and anticipated vortex nucleation. [ABSTRACT FROM AUTHOR]

Published

2011

11. Band-structure loops and multistability in cavity QED.

Author

Venkatesh, B. Prasanna, Larson, J., and O'Dell, D. H. J.

Subjects

*ATOMS, *BOSE-Einstein condensation, *OPTICAL lattices, *OPTICS, *PHYSICS

Abstract

We calculate the band structure of ultracold atoms located inside a laser-driven optical cavity. For parameters where the atom-cavity system exhibits bistability, the atomic band structure develops loop structures akin to the ones predicted for Bose-Einstein condensates in ordinary (noncavity) optical lattices. However, in our case the nonlinearity derives from the cavity back-action rather than from direct interatomic interactions. We find both bi- and tristable regimes associated with the lowest band, and show that the multistability we observe can be analyzed in terms of swallowtail catastrophes. Dynamic and energetic stability of the mean-field solutions is also discussed, and we show that the bistable solutions have, as expected, one unstable and two stable branches. The presence of loops in the atomic band structure has important implications for proposals concerning Bloch oscillations of atoms inside optical cavities [Peden et al., Phys. Rev. A 80, 043803 (2009); Prasanna Venkatesh el at., Phys. Rev. A 80, 063834 (2009)]. [ABSTRACT FROM AUTHOR]

Published

2011

12. Violent relaxation in quantum fluids with long-range interactions.

Author

Plestid, Ryan, Mahon, Perry, and O'Dell, D. H. J.

Subjects

*PERTURBATION theory, *QUANTUM fluids, *STATISTICAL mechanics

Abstract

Violent relaxation is a process that occurs in systems with long-range interactions. It has the peculiar feature of dramatically amplifying small perturbations, and rather than driving the system to equilibrium, it instead leads to slowly evolving configurations known as quasistationary states that fall outside the standard paradigm of statistical mechanics. Violent relaxation was originally identified in gravity-driven stellar dynamics; here, we extend the theory into the quantum regime by developing a quantum version of the Hamiltonian mean field (HMF) model which exemplifies many of the generic properties of long-range interacting systems. The HMF model can either be viewed as describing particles interacting via a cosine potential, or equivalently as the kinetic XY model with infinite-range interactions, and its quantum fluid dynamics can be obtained from a generalized Gross-Pitaevskii equation. We show that singular caustics that form during violent relaxation are regulated by interference effects in a universal way described by Thom's catastrophe theory applied to waves and this leads to emergent length scales and timescales not present in the classical problem. In the deep quantum regime we find that violent relaxation is suppressed altogether by quantum zero-point motion. Our results are relevant to laboratory studies of self-organization in cold atomic gases with long-range interactions. [ABSTRACT FROM AUTHOR]

Published

2018

13. Exploring the stability and dynamics of dipolar matter-wave dark solitons.

Author

Edmonds, M. J., Bland, T., O'Dell, D. H. J., and Parker, N. G.

Subjects

*DE-Broglie waves, *SOLITONS

Abstract

We study the stability, form, and interaction of single and multiple dark solitons in quasi-one-dimensional dipolar Bose-Einstein condensates. The solitons are found numerically as stationary solutions in the moving frame of a nonlocal Gross Pitaevskii equation and characterized as a function of the key experimental parameters, namely the ratio of the dipolar atomic interactions to the van der Waals interactions, the polarization angle, and the condensate width. The solutions and their integrals of motion are strongly affected by the phonon and roton instabilities of the system. Dipolar matter-wave dark solitons propagate without dispersion and collide elastically away from these instabilities, with the dipolar interactions contributing an additional repulsion or attraction to the soliton-soliton interaction. However, close to the instabilities, the collisions are weakly dissipative. [ABSTRACT FROM AUTHOR]

Published

2016

14. Controllable nonlocal interactions between dark solitons in dipolar condensates.

Author

Bland, T., Edmonds, M. J., Proukakis, N. P., Parker, N. G., Martin, A. M., and O'Dell, D. H. J.

Subjects

*SOLITONS, *PRINCIPLE of locality (Physics), *SOLITON collisions, *DIPOLE interactions, *ATOMIC polarization, *NONLINEAR waves

Abstract

We study the family of static and moving dark solitons in quasi-one-dimensional dipolar Bose-Einstein condensates, exploring their modified form and interactions. The density dip of the soliton acts as a giant antidipole which adds a nonlocal contribution to the conventional local soliton-soliton interaction. We map out the stability diagram as a function of the strength and polarization direction of the atomic dipoles, identifying both roton and phonon instabilities. Away from these instabilities, the solitons collide elastically. Varying the polarization direction relative to the condensate axis enables tuning of this nonlocal interaction between repulsive and attractive; the latter case supports unusual dark-soliton bound states. Remarkably, these bound states are themselves shown to behave like solitons, emerging unscathed from collisions with each other. [ABSTRACT FROM AUTHOR]

Published

2015

15. Adiabatic transfer of light in a double cavity and the optical Landau-Zener problem.

Author

Miladinovic, N., Hasan, F., Chisholm, N., Linnington, I. E., Hinds, E. A., and O'Dell, D. H. J.

Subjects

*ELECTROMAGNETIC fields, *PHOTONS, *WAVE equation, *ELECTRODYNAMICS, *ELECTRIC fields

Abstract

We analyze the evolution of an electromagnetic field inside a double cavity when the difference in length between the two cavities is changed, e.g., by translating the common mirror. We find that this allows photons to be moved deterministically from one cavity to the other. We are able to obtain the conditions for adiabatic transfer by first mapping the Maxwell wave equation for the electric field onto a Schrödinger-like wave equation and then using the Landau-Zener result for the transition probability at an avoided crossing. Our analysis reveals that this mapping only rigorously holds when the two cavities are weakly coupled (i.e., in the regime of a highly reflective common mirror) and that, generally speaking, care is required when attempting a Hamiltonian description of cavity electrodynamics with time-dependent boundary conditions. [ABSTRACT FROM AUTHOR]

Published

2011

16. Quantum Spin Dynamics in Fock Space Following Quenches: Caustics and Vortices.

Author

Mumford, J., Turner, E., Sprung, D. W. L., and O'Dell, D. H. J.

Subjects

*QUANTUM theory, *FOCK spaces, *SPHEROMAKS, *PHOTONS

Abstract

Caustics occur widely in dynamics and take on shapes classified by catastrophe theory. At finite wavelengths they produce interference patterns containing networks of vortices (phase singularities). Here we investigate caustics in quantized fields, focusing on the collective dynamics of quantum spins. We show that, following a quench, caustics are generated in the Fock space amplitudes specifying the many-body configuration and which are accessible in experiments with cold atoms, ions, or photons. The granularity of quantum fields removes all singularities, including phase singularities, converting point vortices into nonlocal vortices that annihilate in pairs as the quantization scale is increased. Furthermore, the continuous scaling laws of wave catastrophes are replaced by discrete versions. Such "quantum catastrophes" are expected to be universal dynamical features of quantized fields. [ABSTRACT FROM AUTHOR]

Published

2019

17. Dynamical instability of a rotating dipolar Bose-Einstein condensate.

Author

van Bijnen RM, O'Dell DH, Parker NG, and Martin AM

Abstract

We analyze the hydrodynamic solutions for a dilute Bose-Einstein condensate with long-range dipolar interactions in a rotating, elliptical harmonic trap. The static solutions and their regimes of dynamical instability vary nontrivially with the strength of the dipolar interactions. We comprehensively map out this behavior, and, in particular, examine the experimental routes toward unstable dynamics, which, in analogy to conventional condensates, may lead to vortex lattice formation.

Published

2007

18. Rotons in gaseous Bose-Einstein condensates irradiated by a laser.

Author

O'Dell DH, Giovanazzi S, and Kurizki G

Abstract

A gaseous Bose-Einstein condensate irradiated by a far off-resonance laser has long-range interatomic correlations caused by laser-induced dipole-dipole interactions. These correlations, which are tunable via the laser intensity and frequency, can produce a "roton" minimum in the excitation spectrum--behavior reminiscent of the strongly correlated superfluid liquid He II.

Published

2003