Quenched or alive quantum dots: The leading roles of ligand adsorption and photoinduced protonation

Hypothesis: The fluorescence emission of water-soluble CdTe quantum dots (QDs) capped with mercaptocarboxylic acids (MCAs) is known to be pH-dependent. However, this behaviour is quite different from a study to another, so that literature suffers from a lack of coherence. Here we assume that the QD fluorescence efficiency is actually driven by the acid-base equilibrium of MCA thiol groups, and that light excited QDs open a non-radiative relaxation path through photoinduced protonation. Experiments: We address this issue by examining colloidal CdTe QDs with (time-resolved) fluorescence spectroscopy under various conditions of acidity and light excitation. Findings: It appears that the emission of QDs is quenched below a critical pH value of 6.87, and that light excitation power strengthens this quenching. We thus demonstrate the existence of an additional photochemical process and developed a mathematical modeling accounting for all our experimental results. With only three parameters, it is possible to accurately predict the fluorescence decay of QDs over time, at any pH. Further, we also related the critical pH value of 6.87 to QD surface properties, explaining why observations may differ from a study to another and making the literature much more coherent. ? 2021 Elsevier Inc. All rights reserved.

Automated summary

The fluorescence emission of water-soluble CdTe quantum dots (QDs) capped with mercaptocarboxylic acids (MCAs) is pH-dependent, with emission being quenched below a critical pH of 6.87 and further quenched by light excitation. A mathematical model with three parameters accurately predicts the fluorescence decay of QDs over time, at any pH, linking the critical pH value to QD surface properties and providing coherence to literature with inconsistent observations.