Movies accompanying the paper:
Generating and Manipulating Quantized Vortices On-Demand in A Bose-Einstein Condensate:
A Numerical Study.
B. Gertjerenken,
P.G. Kevrekidis,
R. Carretero-González, and
B.P. Anderson.
Phys. Rev. A 93 (2016) 023604.
[Region I movie (bw=6, v/c=0.07)],
[Region II movie (bw=6, v/c=0.16)],
[Region III movie (bw=6, v/c=0.24)].
Fig. 1: Regions of successful and unsuccessful vortex generation and trapping.
[Fig. 2 movie].
Fig. 2: Controlled generation of a vortex dipole for μ=1.5.
[Fig. 4 movie].
Fig. 4: Generation of an asymmetric vortex dipole.
[Four vortices],
[Six vortices],
[Eight vortices].
Fig. 5: Generation of four, six, and eight vortices.
[Fig. 6 movie].
Fig. 6: Generation of a single vortex.
[Fig. 7 movie].
Fig. 7: Generation of a single vortex in the presence of phenomenological disipation (γ=0.002).
[Fig. 8 movie].
Fig. 8: Generation of a single vortex in the presence of phenomenological disipation (γ=0.0002).
[Fig. 9 movie].
Fig. 9: Generation of a single vortex for improved protocol with circular trajectory.
[Three vortices],
[Five vortices],
[Seven vortices].
Fig. 10: Generation of odd number of vortices.
[Dragging],
[Imprint].
Fig. 11: Comparison between the dragging and imprinting methods.
[Dragging],
[Imprint].
Fig. 13: Same as Fig. 11 but in the presence of phenomenological dissipation (γ=0.02).
[Fig. 14 movie].
Fig. 14: Creating and depositing vortices in repositories for μ=1.5.
[Fig. 15 movie].
Fig. 15: Creating and depositing vortices in repositories for μ=5.
[Fig. 16 movie].
Fig. 16: Same as Fig. 15 but in the presence of phenomenological dissipation (γ=0.02);
