Mean-field phases of an ultracold gas in a quasicrystalline potential

Johnstone, Dean; Öhberg, Patrik; Duncan, Callum W.

doi:10.1103/physreva.100.053609

Cited by 23 publications

(17 citation statements)

References 66 publications

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“…A typical strongly correlated system in optical lattice is the Bose-Hubbard model, where phase transition between Mott insulator (MI) to superfluid (SF) phase appears [39] as experimentally observed [40,41]. Recent achievements in establishing an eight-fold rotationally symmetric optical lattice attract new attention [42], in connection with theoretical investigation of an extended Bose-Hubbard with quasicrystalline confined potential [43], where spontaneous breaking of underlying eight-fold symmetry is observed. However, the effect of aperiodicity in the Bose-Hubbard model is not yet fully understood both theoretically and experimentally.…”

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confidence: 99%

Mean-field study of the Bose-Hubbard model in Penrose lattice

Ghadimi,

Sugimoto,

Tohyama

2020

Preprint

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We examine the Bose-Hubbard model in the Penrose lattice based on inhomogeneous mean-field theory. Since averaged coordination number in the Penrose lattice is four, mean-field phase diagram consisting of the Mott insulator (MI) and superfluid (SF) phase is similar to that of the square lattice. However, the spatial distribution of Bose condensate in the SF phase is significantly different from uniform distribution in the square lattice. We find a fractal structure in its distribution near the MI-SF phase boundary. The emergence of the fractal structure is a consequence of cooperative effect between quasiperiodicity in the Penrose lattice and criticality at the phase transition.

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confidence: 99%

Mean-field study of the Bose-Hubbard model in Penrose lattice

Ghadimi,

Sugimoto,

Tohyama

2020

Preprint

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“…Solid order in region III, which has the most extreme spatial variation of interactions and has significant occupation of both the polar and equatorial sublattices due to repulsion along the axis, builds sharply on the polar sublattice and then gradually on the equatorial sublattice. Spatially-diffuse solid-tunnelling transitions in extended Bose-Hubbard models have previously been predicted due to external mechanisms such as inhomogeneous trapping potentials [58] and varying coordination number in quasicrystal lattices [59], but here this effect is driven entirely by interactions.…”

Section: Discussionmentioning

confidence: 81%

Dipolar Bose-Hubbard Model in finite-size real-space cylindrical lattices

Hughes,

Jaksch

2021

Preprint

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Recent experimental progress in magnetic atoms and polar molecules has created the prospect of simulating dipolar Hubbard models with off-site interactions. When applied to real-space cylindrical optical lattices, these anisotropic dipole-dipole interactions acquire a tunable spatially-dependent component while they remain translationally-invariant in the axial direction, creating a sublattice structure in the azimuthal direction. We numerically study how the coexistence of these classes of interactions affects the ground state of hardcore dipolar bosons at half-filling in a finite-size cylindrical optical lattice with octagonal rings. When these two interaction classes cooperate, we find a solid state where the density order is determined by the azimuthal sublattice structure and builds smoothly as the interaction strength increases. For dipole polarisations where the axial interactions are sufficiently repulsive, the repulsion competes with the sublattice structure, significantly increasing entanglement and creating two distinct ordered density patterns. The spatially-varying interactions cause the emergence of these ordered states as a function of interaction strength to be staggered according to the azimuthal sublattices.

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“…Another interesting question is how the BLT states would appear or alter the physics in the presence of interactions. The study of the physics of two-dimensional quasicrystals including interactions is an emergent topic [96][97][98]. With the recent advances in many-body numerical techniques [99][100][101], the physics of BLT states and their ramifications in quasicrystalline lattices in the many-body regime could soon be probed.…”

Section: Discussionmentioning

confidence: 99%

Bulk Localised Transport States in Infinite and Finite Quasicrystals via Magnetic Aperiodicity

Johnstone,

Colbrook,

Nielsen

et al. 2021

Preprint

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Robust edge transport can occur when charged particles in crystalline lattices interact with an applied external magnetic field. This system is well described by Bloch's theorem, with the spectrum being composed of bands of bulk states and in-gap edge states. When the confining lattice geometry is altered to be quasicrystaline, i.e. quasiperiodic, then Bloch's theorem breaks down. However, for the quasicrystalline system, we still expect to observe the basic characteristics of bulk states and current carrying edge states. Here, we show that for quasicrystals in magnetic fields, there is also a third option; the bulk localised transport states. These states share the in-gap nature of the well-known edge states and can support transport along them, but they are fully contained within the bulk of the system, with no support along the edge. This results in transport being possible both along the edge and within distinct regions of the bulk. We consider both finite-size and infinite-size systems, using rigorous error controlled computational techniques that are not prone to finite-size effects. The bulk localised transport states are preserved for infinite-size systems, in stark contrast to the normal edge states. This allows for transport to be observed in infinite-size systems, without any perturbations, defects, or boundaries being introduced. We confirm the ingap topological nature of the bulk localised transport states for finite and infinite-size systems by computing common topological measures; namely the Bott index and local Chern marker. The bulk localised transport states form due to a magnetic aperiodicity arising from the interplay of length scales between the magnetic field and quasiperiodic lattice. Bulk localised transport could have interesting applications similar to those of the edge states on the boundary, but that could now take advantage of the larger bulk of the lattice. The infinite size techniques introduced here, especially the calculation of topological measures, could also be widely applied to other crystalline, quasicrystalline, and disordered models.

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Mean-field phases of an ultracold gas in a quasicrystalline potential

Cited by 23 publications

References 66 publications

Mean-field study of the Bose-Hubbard model in Penrose lattice

Mean-field study of the Bose-Hubbard model in Penrose lattice

Dipolar Bose-Hubbard Model in finite-size real-space cylindrical lattices

Bulk Localised Transport States in Infinite and Finite Quasicrystals via Magnetic Aperiodicity

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