The precise modification of a nanoscaled Keplerate-type polyoxometalate with NH2-groups: reactive sites, mechanisms and dye conjugation

The interaction of alkoxysilanes with nanoscaled giant polyoxoclusters is a challenging route for efficiently building blocks for supramolecular smart design. 3-Aminopropyltrimethoxysilane (APTMS) treatment grafts amino groups onto the surface of the Keplerate {Mo-132} in a controlled manner. By means of XPS and elemental analysis, we studied the influence of the component ratio, the solvent nature, acidity and mixture preparation on the stoichiometry of POM-APTMS conjugates. The reaction mechanism shows the role of {Mo-2} bridging units as reactive sites for APTMS binding. Comprehensive use of IR and Raman spectroscopy shows ring-like siloxane formation above the {Mo9O9} pores in {Mo-132}. This approach to the covalent modification of giant polyoxometalates (POM) was successfully applied to the functionalization of another Keplerate {Mo70Fe30}. Grafting NH2 groups opened a way to covalently bind POMs with fluorescein-NHS (FL-NHS), where the strong charge transfer near 526 nm (UV-vis) appears to promote potential photocatalytic activities. Studying the conjugates POM-APTMS with SEM, we discovered a novel nano-object consisting of nanostrips: these are unknown for structures based on nanoclusters from the giant POM family. Thus, these pioneering approaches to giant POM covalent functionalization can be applied to designing templates for supramolecular structures and functional materials.

Automated summary

This study demonstrates the covalent modification of giant polyoxometalates (POM) using alkoxysilanes, opening up new possibilities for supramolecular structure design and functional materials.