posted on 2006-09-06, 00:00authored byMaikel Wijtmans, Sandra J. Rosenthal, Binne Zwanenburg, Ned A. Porter
The photochemical properties of organic ligands on the surface of nanocrystalline CdSe particles
were examined. A number of thiols carrying a substituted cinnamate tail was synthesized. In solution, these
cinnamate compounds undergo light-induced (374 nm) E−Z isomerization, followed by a nonphotolytic
lactonization to give highly fluorescent coumarin. The cinnamate-thiols were successfully exchanged onto
the CdSe nanocrystal, and the photochemical behavior of these conjugates was studied. Upon aerobic
photolysis at 374 nm, the surface cinnamates released coumarin accompanied by rapid nanocrystal
degradation. This degradation was not observed under similar anaerobic conditions or when the organic
ligands did not contain the cinnamate group. Surprisingly, very similar results were obtained upon irradiation
at visible wavelengths at which the cinnamate has no absorption. With the aid of UV−visible absorption
spectroscopy, fluorescence spectroscopy, and electrochemistry, a unified theory for both the increased
photoinstability of the nanocrystal as well as the coumarin release was proposed. It involves cinnamate
radical anions on the CdSe surface, formed upon electron transfer from the excited nanocrystal to the
surface cinnamate, undergoing E−Z isomerization. Practically, this results in the remarkable ability to release
coumarin from nanocrystal ligands simply by exciting the nanocrystal with visible light. This new photorelease
protocol not only aids in the understanding of fundamental nanocrystal−ligand interactions but may also
offer new opportunities in the areas of drug delivery and imaging.