Visible and near-infrared photoluminescence of a supramolecular complex constructed from a cycloparaphenylene nanoring and an erbium metallofullerene

Erbium metallofullerenes exhibit near-infrared photoluminescence from the Er3+ ions, which has potential applications in telecommunications, optical devices and bioscience. In this manuscript, we report the construction of a supramolecular complex of metallofullerene Er3N@C-80 and cycloparaphenylene [12]CPP to adjust the near-infrared photoluminescence of Er3N@C-80 through host-guest interactions. Moreover, this supramolecular complex shows a multiwavelength luminescence property. Mass spectrometry, electrochemical measurements and proton NMR spectroscopy were used to characterize the structure of Er3N@C-80 subset of[12]CPP. The electrochemical results of Er3N@C-80 subset of[12]CPP show the negatively shifted redox potentials compared to pristine Er3N@C-80 and the H-1 NMR signals of Er3N@C-80 subset of[12]CPP shift upfield compared to pristine [12]CPP. More importantly, the photoluminescence spectra show that the [12]CPP nanoring can affect the near-infrared emission of encapsulated Er3+ ions in Er3N@C-80, with the characteristic emission peak of Er3+ at 1.5 mu m being broadened and enhanced in the Er3N@C-80 subset of[12]CPP complex, while the fluorescence lifetime of Er3+ also becomes longer after assembly formation. Furthermore, the Er3N@C-80 guest also can influence the photoluminescence property of [12]CPP, whose emission peaks exhibit a slight blue-shift in the Er3N@C-80 subset of[12]CPP complex. This study illustrates that the outer nanoring can be employed to adjust the photoluminescence of the encapsulated Er3+ ion in Er3N@C-80.

Automated summary

In this study, a supramolecular complex of metallofullerene Er3N@C-80 and cycloparaphenylene [12]CPP was constructed to adjust the near-infrared photoluminescence of Er3N@C-80 through host-guest interactions. The results showed that the nanoring can affect the emission peak and fluorescence lifetime of the encapsulated Er3+ ions.