Abstract
Self-assembly of fundamental elements through weak, long-range interactions plays a central role in both supramolecular DNA assembly and bottom-up synthesis of nanostructures. Optical solitons, analogous in many ways to particles, arise from the balance between nonlinearity and dispersion and have been studied in numerous optical systems. Although both short- and long-range interactions between optical solitons have attracted extensive interest for decades, stable soliton supramolecules, with multiple aspects of complexity and flexibility, have thus far escaped experimental observation due to the absence of techniques for enhancing and controlling the long-range inter-soliton forces. Here we report that long-range soliton interactions originating from optoacoustic effects and dispersive-wave radiations can be precisely tailored in a fibre laser cavity, enabling self-assembly of large numbers of optical solitons into highly-ordered supramolecular structures. We demonstrate several features of such optical structures, highlighting their potential applications in optical information storage and ultrafast laser-field manipulation.
Highlights
Self-assembly of fundamental elements through weak, long-range interactions plays a central role in both supramolecular DNA assembly and bottom-up synthesis of nanostructures
We recently reported that intense optomechanical effects in a short length of solid-core photonic crystal fibre (PCF) could be used to form a robust, GHz-rate optomechanical lattice in a soliton fibre laser[32,33,34] and that individual solitons could be selectively erased by launching precisely timed erasing pulses[5]
In this paper we report that long-range forces of different physical origin between a variety of solitonic elements can be widely tailored to cooperate with each other in a fibre laser cavity, leading to the self-assembly of a large population of optical solitons into highly-ordered, supramolecular structures[35,36]
Summary
Self-assembly of fundamental elements through weak, long-range interactions plays a central role in both supramolecular DNA assembly and bottom-up synthesis of nanostructures. In this paper we report that long-range forces of different physical origin between a variety of solitonic elements can be widely tailored to cooperate with each other in a fibre laser cavity, leading to the self-assembly of a large population of optical solitons into highly-ordered, supramolecular structures[35,36]. These structures are found to exhibit unprecedented complexity in their configuration, multiple degrees of freedom, while at the same time featuring long-term stability, elementary diversity, structural flexibility, and reversibility
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