Stable (2+1)-dimensional soliton and breather molecules in a cold Rydberg atomic gas
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Abstract
We investigate the formation of stable (2+1)-dimensional spatial-domain optical soliton molecules and breather molecules in a gas of Rydberg atoms, highlighting the role of the nonlocal nonlinearity, which is generated by the electromagnetically induced transparency in the Rydberg medium.
The setting supports diverse species of large-size polygonal soliton molecules, including rectangular and oblique rhombuses, checkerboard cells, and hexagons.
The analysis identifies two distinct formation regimes.
In the case of moderately nonlocality, the long-range interactions alone stabilize the soliton molecules in the static form.
In contrast, in the strongly nonlocal regime, initially imposed rotation is required to generate a centrifugal force that counteracts the strong attraction, resulting in stably rotating soliton molecules.
The rotation period can be controlled by adjusting the system parameters.
Furthermore, appropriate initial velocities can induce inherent breathing dynamics in the solitons, leading to the formation of breather molecules.
Tuning the initial velocity, one can control the evolution of soliton molecules and breather molecules and even realize their mutual conversion.
Our study offers a new scheme for engineering soliton molecules and breather molecules, and suggests new possibilities for the design of data processing and transmission in optical systems.