Formation of Prenucleation Clusters and Transformation to ZnSe Quantum Dots and Magic-Size Clusters

Abstract

Prenucleation clusters (PNCs) play an important role in the synthesis of colloidal semiconductor quantum dots (QDs) and magic-size clusters (MSCs) of binary II-VI metal chalcogenide (ME). Here, we explore the formation and transformation of ZnSe PNCs, using a reaction of zinc oleate (Zn(OA)2), tri-n-octylphosphine selenide (SeTOP), and diphenylphosphine (HPPh2, DPP). The PNC forms above 120 C, and relatively high feed concentrations and Zn-to-Se molar ratios favor the formation. When a prenucleation-stage sample (160 C/30 min) is dispersed in a mixture of cyclohexane (CH) and octylamine (OTA) at 25 C, MSC-299 (displaying optical absorption peaking at 299 nm) develops from the PNC isomerization. The PNC is the precursor compound (PC-299) of MSC-299 and is relatively transparent. When the reaction is heated at higher temperatures (such as 220 C for 15 min), the PNC fragments to monomers (Mos) and the nucleation and growth (N/G) of QDs occur (via the one-by-one addition of Mos). In a mixture of CH and CH3OH at 25 C, MSC-299 transforms to MSC-320 and MSC-340. The present study provides a deeper understanding of the formation and transformation of ZnSe PNCs.