Raman Tweezers Microspectroscopy of Functionalized 4.2-nm Diameter CdSe Nanocrystals in Water Reveals Changed Ligand Vibrational Modes by a Metal Cation

R. Mrad , S.G. Kruglik , N. Ben Brahim , R. Ben Chaabane , M. Negrerie

Bibtex , URL
Journal of Physical Chemistry C, 123, 40, 24912-24918
Published 18 Sep. 2019
DOI: 10.1021/acs.jpcc.9b06756

Abstract

We demonstrated the possibility of acquiring Raman spectra of colloidal quantum dots (QDs) at low concentration in water with a size as small as 2.5 nm in diameter using Raman tweezers microspectroscopy. We measured the spectra of CdSe QDs capped with thioglycerol and with l-cysteine. This technique was applied to probe the interaction between Co2+ and Cys–CdSe QDs whose fluorescence emission is quenched in the presence of this metal cation. The quenching mechanism was so far hypothetical. The Raman spectra of Cys–CdSe QDs recorded in the absence and in the presence of Co2+ demonstrated the binding of Co2+ cations to the carboxylate groups of the l-cysteine ligand grafted on the surface of the 4.2 nm CdSe QDs. The frequency of modes for the grafted ligand is changed with respect to the free ligand in solution. Considering the vibrational coupling between the excitonic state and the ligand, we inferred that the binding of a metal cation to the grafted ligand modifies this coupling, so that exciton relaxation through crystal defects is favored. This result rationalizes the fluorescence quenching observed during the metal cation–QD interaction.