Former students
Falk Scharnberg (PhD)
Shannon Whitlock (PhD)
Stephen McDonald (Honours)
Michael Pullen (Honours)
Tim Mapperson
Sven Teichmann
Alan Leigh

Double well sensor of asymmetry in trapping potentials

Adiabatic splitting of a rubidium condensate in an asymmetric double-well potential leads to an unequal distribution of atoms in the wells. Precise measurements of the number of atoms in each well provide information about an asymmetrical component of the trapping potential. This non-interferometric method can be used for the construction of a new sensor which is sensitive to small-scale variations of a gravitational force.

Paper: B.V. Hall et al, Phys. Rev. Lett. 98, 030402 (2007) 

Disordered potential and multiple BECs

We have found that cold rubidium clouds are fragmented above the magnetic film atom chip. Inhomogeneity in the film magnetisation generates a corrugation term in the axial trapping potential. Using a combination of RF spectroscopy, optical imaging and the truncated Boltzmann distribution we qualitatively characterised spatial variations of the disordered magnetic field. Our model produces analytical expressions consistent with the observations and predicts a y^-2 decay of the random field amplitude. Ten independent condensates were produced via evaporative cooling of a highly elongated cloud.

Paper: S. Whitlock et al, Phys. Rev. A 75, 043602 (2007)

Bose-Einstein condensation on a magnetic film atom chip

We have developed a hybrid atom chip comprising a magnetic film TbGdFeCo with perpendicular magnetisation and current-carrying silver wires.  This design allows us to combine the stability of permanent magnetic fields with versatility of time-variable magnetic fields.  We observe the heating rate of 3 nK/s when the atoms are confined in the magnetic film trap.  We produce a Bose condensate of 200,000 rubidium atoms using either a Z-shaped current or the magnetic film trap.

Papers:
B.V. Hall et al, Journal of Physics B 39, 27 (2006)         (Highlights of J. Physics B for 2006)
B.V. Hall et al, Laser Spectroscopy XVII, 275 (2005) 
S. Whitlock et al, Australian Physics 43, No.1, 8 (2006)

Magnetic films for atom optics

Permanent magnetic materials can produce sophisticated magnetic field configurations and offer an alternative to current-carrying wires for the construction of miniature optical elements on atom chips. Gd₁₀Tb₆Fe₈₀Co₄ magneto-optical films have large perpendicular magnetic anisotropy and are suitable for the production of periodically grooved, micron-scale structures. We studied the deposition process and properties of GdTbFeCo films that make them suitable for the applications on the atom chips.

Paper: J. Wang et al , Journal of Physics D 38, 4015 (2005)

Asymmetric potential in double-well atom interferometry

We examine the effect of asymmetry on a splitting process in a double-well interferometer. The interferometer involves a measurement of the first excited state population as a sensitive measure of the asymmetric potential. The Bloch vector model and multi-mode numerical simulations account for the effect of asymmetry and the role of adiabaticity throughout the interferometric process and allow appropriate time scales to be chosenfor the splitting and merging stages.

Paper: A.I. Sidorov et al, Phys. Rev A 74, 023612 (2006)

Theory of decoherence in BEC interferometry

A theory of BEC interferometry in an unsymmetrical double-well trap has been developed for small boson numbers, based on the two-mode approximation. The bosons are initially in the lowest mode of a single well trap, which is split into a double well and then recombined. Possible fragmentations into separate BEC states in each well during the splitting and recombination processes are allowed for. Self-consistent sets of equations for the amplitudes of the fragmented states and for the two single boson mode functions are obtained. The latter are coupled Gross-Pitaevskii equations. Interferometric effects may be measured via boson numbers in the first excited mode.
A full treatment of decoherence and dephasing effects in BEC interferometry is being developed, based on using quantum correlation functions for describing interferometric effects. The BEC is described via a phase space distribution functional of the Wigner type for the condensate modes and the positive P type for the non-condensate modes. Ito equations for stochastic condensate and non-condensate field functions replace the functional Fokker-Planck equation for the distribution functional and stochastic averages of field function products determine the quantum correlation functions.

Papers: B.J. Dalton, J. Mod. Opt. 54, 615 (2007); J. Phys: Conference Series 67 012059 (2007)