Numerical simulations reveal that tilting dipolar atoms in rotating BECs drives a square-to-triangular vortex lattice transition, vortex elimination beyond the magic angle, and LHY-enabled vortex formation or fragmentation depending on orientation and rotation strength.
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Mean-field calculations reveal magic tilt angles triggering transitions between checkerboard finite-momentum and stripe supersolid phases in spin-orbit-coupled dipolar bosons.
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Structural transition and fragmentation of vortex lattices in rotating tilted dipolar Bose-Einstein condensate
Numerical simulations reveal that tilting dipolar atoms in rotating BECs drives a square-to-triangular vortex lattice transition, vortex elimination beyond the magic angle, and LHY-enabled vortex formation or fragmentation depending on orientation and rotation strength.
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Magnetic quantum phases of spin-orbit-coupled anisotropic dipolar bosons in square lattices
Mean-field calculations reveal magic tilt angles triggering transitions between checkerboard finite-momentum and stripe supersolid phases in spin-orbit-coupled dipolar bosons.