Decoherence of Bose-Einstein condensates in microtraps

Henkel, Carsten; Gardiner, S. A.

doi:10.1103/physreva.69.043602

Cited by 15 publications

(13 citation statements)

References 40 publications

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“…In the linearized excitation approach, this corresponds to unequally spaced energy levels due to the deviation from the harmonic approximation. Note that similar oscillations have been observed in [49] for an oscillator and a certain scenario of spatial decoherence.…”

Section: Number Conserving Noise (No Loss)supporting

confidence: 79%

“…The decoherence rate for rotations aroundŜ 1 (cyan curve) oscillates between G = 0 1 and g G = 1 and then starts to increase gradually. The decoherence rate G 3 (phase noise, blue curve) oscillates between γ and g x 4 and then stabilizes with the average value g x G » + -( ) 1 2 3 4 of equation (49). The fastest decay of coherence is found for number noise (red curve, a = 2) because random rotations around this axis displace the squeezed ensemble significantly from its equilibrium position.…”

Section: Number Conserving Noise (No Loss)mentioning

confidence: 94%

“…A pronounced feature of the evolution is the oscillatory decay of the coherence. In the derivation of equation (49), it was assumed that the Josephson oscillations spread the semiclassical ensemble throughout the pertinent classical orbit. However, it may happen that diffusion due to the noise leads to an ensemble with an oscillating width.…”

Section: Number Conserving Noise (No Loss)mentioning

confidence: 99%

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Suppression and enhancement of decoherence in an atomic Josephson junction

et al. 2016

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We investigate the role of interatomic interactions when a Bose gas, in a double-well potential with a finite tunneling probability (a 'Bose-Josephson junction'), is exposed to external noise. We examine the rate of decoherence of a system initially in its ground state with equal probability amplitudes in both sites. The noise may induce two kinds of effects: firstly, random shifts in the relative phase or number difference between the two wells and secondly, loss of atoms from the trap. The effects of induced phase fluctuations are mitigated by atom-atom interactions and tunneling, such that the dephasing rate may be suppressed by half its single-atom value. Random fluctuations may also be induced in the population difference between the wells, in which case atom-atom interactions considerably enhance the decoherence rate. A similar scenario is predicted for the case of atom loss, even if the loss rates from the two sites are equal. We find that if the initial state is number-squeezed due to interactions, then the loss process induces population fluctuations that reduce the coherence across the junction. We examine the parameters relevant for these effects in a typical atom chip device, using a simple model of the trapping potential, experimental data, and the theory of magnetic field fluctuations near metallic conductors. These results provide a framework for mapping the dynamical range of barriers engineered for specific applications and set the stage for more complex atom circuits ('atomtronics'). Figure 4. Decoherence induced by loss. A loss rate g = J 0.08 loss is applied, such that after = t J 10 only ∼45% of the atoms are left in the trap. During this time the coherence drops due to interactions. We have used N=50 atoms in the numerical simulation, showing two curves, for onsite interaction strengths = U J 0.2 [u = 10] and U=J [u = 50]. (a) coherence as a function of time. (b) instantaneous rate of decoherence, showing oscillations with half the Josephson period w = ( J 3.32 J and J 7.14 for the two curves).

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Section: Number Conserving Noise (No Loss)supporting

confidence: 79%

Section: Number Conserving Noise (No Loss)mentioning

confidence: 94%

Section: Number Conserving Noise (No Loss)mentioning

confidence: 99%

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Suppression and enhancement of decoherence in an atomic Josephson junction

et al. 2016

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“…These results should motivate further investigations to elucidate the interplay amongst tunneling, atomic collisions, and effects due to external noise, and their role in maintaining robust spatial coherence [39,[50][51][52]. This experiment also holds promise for the future development of atomic circuits.…”

Section: Discussionmentioning

confidence: 84%

Robust spatial coherence5μmfrom a room-temperature atom chip

et al. 2016

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We study spatial coherence near a classical environment by loading a Bose-Einstein condensate into a magnetic lattice potential and observing diffraction. Even very close to a surface (5 µm), and even when the surface is at room temperature, spatial coherence persists for a relatively long time (≥ 500 ms). In addition, the observed spatial coherence extends over several lattice sites, a significantly greater distance than the atom-surface separation. This opens the door for atomic circuits, and may help elucidate the interplay between spatial dephasing, inter-atomic interactions, and external noise.

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“…These achievements are significant since a BEC is the most likely source to feed atom-optical devices as they provide a large number of coherent atoms. In fact, the controlled propagation of BEC's through atom chip waveguides has already been demonstrated [11][12][13], and some sources of decoherence have been identified [8,14,15].…”

Section: Introductionmentioning

confidence: 99%

Classical aspects of ultracold atom wave packet motion through microstructured waveguide bends

Bromley

Esry

2004

Phys. Rev. A

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The properties of low-density, low-energy matter wave packets propagating through waveguide bends are investigated. Time-dependent quantum-mechanical calculations using simple harmonic oscillator confining potentials are performed for a range of parameters close to those accessible by recent "atom chip"-based experiments. We compare classical calculations based on Ehrenfest's theorem to these results to determine whether classical mechanics can predict the amount of transverse excitation as measured by the transverse heating. The present results thus elucidate some of the limits for which matter wave propagation through microstructures can be reliably considered using classical particle motion.

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Decoherence of Bose-Einstein condensates in microtraps

Cited by 15 publications

References 40 publications

Suppression and enhancement of decoherence in an atomic Josephson junction

Suppression and enhancement of decoherence in an atomic Josephson junction

Robust spatial coherence5μmfrom a room-temperature atom chip

Classical aspects of ultracold atom wave packet motion through microstructured waveguide bends

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