We theoretically investigate the merging behavior of two identical supersolids through dipolar Bose-Einstein condensates confined within a double-well potential. By adiabatically tuning the barrier height and the spacing between the two wells for specific trap aspect ratios, the two supersolids move toward each other and lead to the emergence of a variety of ground-state phases, including a supersolid state, a macrodroplet state, a ring state, and a labyrinth state. We construct a phase diagram that characterizes various states seen during the merging transition. Further, we calculate the force required to pull the two portions of the gas apart, finding that the merged supersolids act like a deformable plastic material. Our work paves the way for future studies of layer structure in dipolar supersolids and the interaction between them in experiments.
BT - Physical Review A DA - 2024-01 DO - 10.1103/physreva.109.013307 IS - 1 N2 -We theoretically investigate the merging behavior of two identical supersolids through dipolar Bose-Einstein condensates confined within a double-well potential. By adiabatically tuning the barrier height and the spacing between the two wells for specific trap aspect ratios, the two supersolids move toward each other and lead to the emergence of a variety of ground-state phases, including a supersolid state, a macrodroplet state, a ring state, and a labyrinth state. We construct a phase diagram that characterizes various states seen during the merging transition. Further, we calculate the force required to pull the two portions of the gas apart, finding that the merged supersolids act like a deformable plastic material. Our work paves the way for future studies of layer structure in dipolar supersolids and the interaction between them in experiments.
PB - American Physical Society (APS) PY - 2024 T2 - Physical Review A TI - Merging dipolar supersolids in a double-well potential VL - 109 SN - 2469-9926, 2469-9934 ER -