Abstract
Little is known about the formation pathway of colloidal semiconductor magic‐size clusters (MSCs). Here, the synthesis of the first single‐ensemble ZnSe MSCs, which exhibit a sharp optical absorption singlet peaking at 299 nm, is reported; their formation is independent of Zn and Se precursors used. It is proposed that the formation of MSCs starts with precursor self‐assembly followed by Zn and Se covalent bond formation to result in immediate precursors (IPs) which can transform into the MSCs. It is demonstrated that the IPs in cyclohexane appear transparent in optical absorption, and become visible as MSCs exhibiting one sharp optical absorption peak when a primary amine is added at room temperature. It is shown that when the preparation of the IP is controlled to be within the induction period, which occurs prior to nucleation and growth of conventional quantum dots (QDs), the resulting MSCs can be produced without the complication of the simultaneous coproduction of conventional QDs. The present study reveals the existence of precursor self‐assembly which leads to the formation of colloidal semiconductor MSCs and provides insights into a multistep nucleation process in cluster science.
Highlights
zinc selenide (ZnSe) magic-size clusters (MSCs), which exhibit a sharp optical absorption singlet peaking at 299 nm, is reported; their formation is independent of Zn and Se precursors used
We have demonstrated that precursor self-assembly can be a general pathway for the formation of colloidal semiconductor MSCs, based on a study of the ZnSe model system (Scheme 1 and Scheme S1, Supporting Information)
The formation of immediate precursors (IPs)-299 occurs in the first step; the underlying cause is attributed to a dense phase reaction for the former driven by precursor self-assembly
Summary
For our investigation on the formation pathway of MSCs, we used ZnSe as a model system, exploring the above reactions with experimental conditions optimized for the first step of a two-step approach to MSC-299. For the optical spectra reported,[44–48] the absorption peaks, which were relatively narrow and/or persistent, occurred at ≈279, 289, 328, and 347 nm. Optical absorption spectroscopy was used to explore the induction period of each of the reactions, for the presence of IP-299 which led to the formation of ZnSe MSC-299. We discuss in Note S1 (Supporting Information) the challenge of conventional characterization tools for the size and structure of the MSCs
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