The lattice melting transition in a two-dimensional BEC
ORAL
Abstract
The ground state of a rapidly rotating superfluid is an Abrikosov lattice of quantised vortices, which is akin to a crystalline solid and defines the zero-temperature state of a two-dimensional system of single sign vortices. At sufficiently higher energies, the lattice melts and can be approximated as a strongly correlated vortex liquid. These states of vortex matter have gained prominence in the theory of the fractional quantum hall effect, where the 2D electron gas moves analogous to vortices in an incompressible fluid, and the vortex density maps to the density of the quantum hall droplet.
The development of quasi-2D BEC superfluids in optical box potentials has resulted in new experimental systems for exploring the dynamics of point-like vortices [1, 2]. In this work, we experimentally observe the low energy phases of chiral vortex matter, including the predicted excess edge density at the vortex cluster edge [3]. The experiment initialises a vortex lattice in a disc-shaped BEC by rearranging 19 optically-pinned vortices to realise a vortex crystal of arbitrary size. The vortices are then released from the pins, and the vortex lattice melts as it gains energy from small-scale vibrations of the optical trapping potential. After several seconds of hold time, a robust signature of the edge density overshoot is observed. At longer hold times, the crystal melts fully. While facilitating the exploration of low-energy vortex configurations, this work also refines experimental techniques for creating arbitrary arrangements of vortices, paving the way for experiments in more complex trap geometries.
[1] G. Gauthier, M. T. Reeves, X. Yu, A. S. Bradley, M. A. Baker, T. A. Bell, H. Rubinsztein-Dunlop, M. J. Davis, T. W. Neely, Science 364, 1264-1267 (2019).
[2] M. T. Reeves, K. Goddard-Lee, G. Gauthier, O. R. Stockdale, H. Salman, T. Edmonds, X. Yu, A. S. Bradley, M. Baker, H. Rubinsztein-Dunlop, M. J. Davis, T. W. Neely, Physical Review X, 12, 011031 (2022).
[3] A. Bogatskiy and P. Wiegmann. Edge Wave and Boundary Layer of Vortex Matter, Physical Review Letters 122, 214505 (2019).
The development of quasi-2D BEC superfluids in optical box potentials has resulted in new experimental systems for exploring the dynamics of point-like vortices [1, 2]. In this work, we experimentally observe the low energy phases of chiral vortex matter, including the predicted excess edge density at the vortex cluster edge [3]. The experiment initialises a vortex lattice in a disc-shaped BEC by rearranging 19 optically-pinned vortices to realise a vortex crystal of arbitrary size. The vortices are then released from the pins, and the vortex lattice melts as it gains energy from small-scale vibrations of the optical trapping potential. After several seconds of hold time, a robust signature of the edge density overshoot is observed. At longer hold times, the crystal melts fully. While facilitating the exploration of low-energy vortex configurations, this work also refines experimental techniques for creating arbitrary arrangements of vortices, paving the way for experiments in more complex trap geometries.
[1] G. Gauthier, M. T. Reeves, X. Yu, A. S. Bradley, M. A. Baker, T. A. Bell, H. Rubinsztein-Dunlop, M. J. Davis, T. W. Neely, Science 364, 1264-1267 (2019).
[2] M. T. Reeves, K. Goddard-Lee, G. Gauthier, O. R. Stockdale, H. Salman, T. Edmonds, X. Yu, A. S. Bradley, M. Baker, H. Rubinsztein-Dunlop, M. J. Davis, T. W. Neely, Physical Review X, 12, 011031 (2022).
[3] A. Bogatskiy and P. Wiegmann. Edge Wave and Boundary Layer of Vortex Matter, Physical Review Letters 122, 214505 (2019).
–
Presenters
-
Tyler W Neely
University of Queensland
Authors
-
Tyler W Neely
University of Queensland
-
Matthew T Reeves
University of Queensland
-
Charles Glasspool
University of Queensland
-
Guillaume Gauthier
University of Queensland
-
Matthew J Davis
University of Queensland, Univ of Queensland, The University of Queensland,
-
Halina Rubinsztein-Dunlop
University of Queensland, The University of Queensland,