posted on 2019-02-06, 00:00authored byZonglin Chu, Yanxiao Han, Tong Bian, Soumen De, Petr Král, Rafal Klajn
The reversible photoisomerization
of azobenzene has been utilized
to construct a plethora of systems in which optical, electronic, catalytic,
and other properties can be controlled by light. However, owing to
azobenzene’s hydrophobic nature, most of these examples have
been realized only in organic solvents, and systems operating in water
are relatively scarce. Here, we show that by coadsorbing the inherently
hydrophobic azobenzenes with water-solubilizing ligands on the same
nanoparticulate platforms, it is possible to render them essentially
water-soluble. To this end, we developed a modified nanoparticle functionalization
procedure allowing us to precisely fine-tune the amount of azobenzene
on the functionalized nanoparticles. Molecular dynamics simulations
helped us to identify two distinct supramolecular architectures (depending
on the length of the background ligand) on these nanoparticles, which
can explain their excellent aqueous solubilities. Azobenzenes adsorbed
on these water-soluble nanoparticles exhibit highly reversible photoisomerization
upon exposure to UV and visible light. Importantly, the mixed-monolayer
approach allowed us to systematically investigate how the background
ligand affects the switching properties of azobenzene. We found that
the nature of the background ligand has a profound effect on the kinetics
of azobenzene switching. For example, a hydroxy-terminated background
ligand is capable of accelerating the back-isomerization reaction
by more than 6000-fold. These results pave the way toward the development
of novel light-responsive nanomaterials operating in aqueous media
and, in the long run, in biological environments.