Litcius/Paper detail

Highly Efficient Artificial Light-Harvesting Systems Constructed in an Aqueous Solution Based on Twisted Cucurbit[14]Uril

Yang Luo, Wei Zhang, Qian Ren, Zhu Tao, Xin Xiao

2022ACS Applied Materials & Interfaces27 citationsDOI

Abstract

Relying on the supramolecular self-assembly of twisted cucurbit[14]urils (tQ[14]), anthracene derivatives (ADPy), Nile red (NiR), and rhodamine B (RB), highly efficient light-harvesting systems have been successfully designed in an aqueous medium. The addition of tQ[14] causes ADPy to aggregate through supramolecular self-assembly to form a supramolecular polymer (ADPy@tQ[14]) with excellent aggregation-induced fluorescence and an interesting spherical external morphology, making it a remarkable energy donor. Consequently, efficient energy-transfer processes have occurred between ADPy@tQ[14] assembly and NiR and RB, which both serve as effective energy acceptors while being loaded onto ADPy@tQ[14]. In the case of NiR, the energy-transfer efficiency is up to 72.45%, and the antenna effect is near 55.4 at a donor/acceptor ratio of 100:1, making it close to the light-harvesting systems in nature. As a result, effective water-soluble artificial light-harvesting systems are showing enormous prospective as versatile platforms for simulating photosynthesis.

Topics & Concepts

Supramolecular chemistryMaterials scienceAqueous solutionRhodamine BAnthraceneFluorescenceArtificial photosynthesisEnergy harvestingNanotechnologyEnergy transferSupramolecular polymersAcceptorRhodamineSelf-assemblyNile redSupramolecular assemblyPhotochemistryEnergy (signal processing)Chemical physicsOrganic chemistryOpticsMoleculeChemistryMathematicsPhysicsCatalysisStatisticsPhotocatalysisCondensed matter physicsLuminescence and Fluorescent MaterialsSupramolecular Chemistry and ComplexesSupramolecular Self-Assembly in Materials