Adiabatically induced coherent Josephson oscillations of ultracold atoms in an asymmetric two-dimensional magnetic lattice

Abdelrahman, Ahmed; Hannaford, Peter; Alameh, Kamal

doi:10.1364/oe.17.024358

Cited by 15 publications

(6 citation statements)

References 34 publications

(42 reference statements)

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“…Usually, the periodic potential is created as an optical lattice, OL, which is induced by the interference of coherent laser beams illuminating the condensate, as proposed by Jaksch et al (1998) and demonstrated by Greiner et al (2002). More recently, it was demonstrated by Ghanbari, Kieu, Sidorov, and Hannaford (2006), and by Abdelrahman, Hannaford, and Alameh (2009) that 2D and 1D periodic potentials may also be induced by magnetic lattices, created by a plate made of a permanent magnet with a lattice of holes drilled in it, or more sophisticated variants of this setting.…”

Section: B Bose-einstein Condensatesmentioning

confidence: 99%

Solitons in nonlinear lattices

2011

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This article offers a comprehensive survey of results obtained for solitons and complex nonlinear wave patterns supported by purely nonlinear lattices (NLs), which represent a spatially periodic modulation of the local strength and sign of the nonlinearity, and their combinations with linear lattices. A majority of the results obtained, thus far, in this field and reviewed in this article are theoretical. Nevertheless, relevant experimental settings are surveyed too, with emphasis on perspectives for implementation of the theoretical predictions in the experiment. Physical systems discussed in the review belong to the realms of nonlinear optics (including artificial optical media, such as photonic crystals, and plasmonics) and Bose-Einstein condensation (BEC). The solitons are considered in one, two, and three dimensions (1D, 2D, and 3D). Basic properties of the solitons presented in the review are their existence, stability, and mobility. Although the field is still far from completion, general conclusions can be drawn. In particular, a novel fundamental property of 1D solitons, which does not occur in the absence of NLs, is a finite threshold value of the soliton norm, necessary for their existence. In multidimensional settings, the stability of solitons supported by the spatial modulation of the nonlinearity is a truly challenging problem, for the theoretical and experimental studies alike. In both the 1D and 2D cases, the mechanism which creates solitons in NLs is principally different from its counterpart in linear lattices, as the solitons are created directly, rather than bifurcating from Bloch modes of linear lattices.Peer ReviewedPostprint (published version

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Section: B Bose-einstein Condensatesmentioning

confidence: 99%

Solitons in nonlinear lattices

2011

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“…This in turn will inform experiments in which we will attempt to achieve our ultimate goal of trapping a single atom in the potential well created by a DW. Nanowire arrays with geometries similar to that which we have investigated in this paper could ultimately be used to create two dimensional arrays of magnetic traps, which have been shown to be useful tools for studying phenomena such as Josephson oscillations [41] and Mott insulator transitions [42] in atomic ensembles. The inset figure shows the differential of the data in the region of the "on" to "q-off" transition for the negative field sweep.…”

Section: Discussionmentioning

confidence: 99%

Design and characterization of a field-switchable nanomagnetic atom mirror

Hayward

West

Weatherill

et al. 2010

Journal of Applied Physics

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We present a design for a switchable nanomagnetic atom mirror formed by an array of 180° domain walls confined within Ni 80 Fe 20 planar nanowires. A simple analytical model is developed which allows the magnetic field produced by the domain wall array to be calculated. This model is then used to optimize the geometry of the nanowires so as to maximize the reflectivity of the atom mirror. We then describe the fabrication of a nanowire array and characterize its magnetic behavior using magneto-optic Kerr effect magnetometry, scanning Hall probe microscopy and micromagnetic simulations, demonstrating how the mobility of the domain walls allow the atom mirror to be switched "on" and "off" in a manner which would be impossible for conventional designs. Finally, we model the reflection of 87 Rb atoms from the atom mirror's surface, showing that our design is well suited for investigating interactions between domain walls and cold atoms.

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“…Periodic arrays of magnetic microtraps created by arrays of current-carrying wires [11,12] and permanent magnetic slabs [13][14][15][16][17][18][19][20] have been introduced for trapping and manipulating ultracold atoms. They have been used in fundamental researches on ultracold atoms including quantum degenerate gases and BECs [21].…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, 2D lattices of magnetic microtraps produced by crossed arrays of current-carrying wires have been proposed [26,27]. So far, several configurations of permanent magnetic lattices have been proposed [13][14][15][16][17][18][19][20]. In reference [13], arrays of permanent magnetic waveguides and the first 2D permanent magnetic lattice consisting of arrays of either rectangular or square slabs has been proposed.…”

Section: Introductionmentioning

confidence: 99%

3D permanent magnetic lattices for ultracold atoms

Ghanbari

2023

Phys. Scr.

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We introduce 3D permanent magnetic lattices for ultracold atoms which can be created by arbitrary number of 2D arrays of square permanent magnetic slabs plus a bias magnetic field. Instead of the square magnets, we can also use magnetic films with square holes. We find analytical expressions for the location of the nonzero magnetic field minima and physical quantities such as trap depths, absolute value of the magnetic field and curvatures as well as trap frequencies at each minimum. We show that most of them, including the trap depths, modulation depths, and trap frequencies can be controlled by the bias field. Accessible trap depths and trap frequencies in the permanent magnetic lattices are much higher compared to the optical lattices. Between the magnetic layers, the trap frequencies are higher compared to above the top layer (under the bottom layer). In principle, our method can be generalized to other 2D permanent magnetic lattices and we show how to transform a 2D lattice of a given geometry into 3D by using multiple layers of magnets.

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Adiabatically induced coherent Josephson oscillations of ultracold atoms in an asymmetric two-dimensional magnetic lattice

Cited by 15 publications

References 34 publications

Solitons in nonlinear lattices

Solitons in nonlinear lattices

Design and characterization of a field-switchable nanomagnetic atom mirror

3D permanent magnetic lattices for ultracold atoms

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