posted on 2017-06-21, 18:10authored byTingting Zhu, Baowei Zhang, Jing Zhang, Jiao Lu, Hongsong Fan, Nelson Rowell, John A. Ripmeester, Shuo Han, Kui Yu
Nucleation has been generally acknowledged
as a rapid but uncontrollable
process that is difficult to decouple from the subsequent growth phase.
Here, we report our finding that nucleation of semiconductor magic-size
clusters (MSCs) can be well-regulated, without a subsequent evolution
in size. Colloidal semiconductor CdS MSCs were synthesized by a two-step
approach intentionally designed, without the simultaneous formation
of nanocrystals of other sizes. The nuclei MSCs exhibit a sharp optical
absorption peaking at 311 nm and are thus denoted by MSC–311.
We prepared the immediate precursor for MSC–311 denoted by
IP311 which is liquid-like, through a reaction which was normally
performed to grow CdS conventional quantum dots (QDs), but at a different
temperature (180 °C) prior to the nucleation and growth of CdS
QDs. We demonstrate that the nucleation of MSC–311 from IP311
followed first order kinetics remarkably well, and the presence of
a small amount of methanol accelerated this process effectively. Moreover,
the liquid-like prenucleation cluster IP311 and the nuclei MSC–311
have similar masses. Accordingly, we propose that the intramolecular
reorganization of IP311 results in the nuclei MSC–311, the
formation of which features a two-step nucleation pathway. The present
study introduces methodology via absorption spectroscopy to monitor
the nucleation kinetics of semiconductor MSCs from their immediate
precursors. The repeatable, predictable, and controllable nucleation
process investigated here brings a deeper insight into nucleation
of other semiconductor nanocrystals and contributes to the foundation
for the future development of advanced theoretical models for crystal
nucleation.