Shape‐ and Phase‐Controlled Synthesis of Monodisperse, Single‐Crystalline Ternary Chalcogenide Colloids through a Convenient Solution Synthesis Strategy

Abstract

Colloidal, monodisperse, single-crystalline pyramidal CuInS₂ and rectangular AgInS₂ nanocrystals were successfully synthesized through a convenient and improved solvothermal process that uses hexadecylamine as a capping reagent. The crystal phase, morphology, crystal lattice, and chemical composition of the as-prepared products were characterized by using X-ray diffraction, transmission electron microscopy (TEM), high-resolution TEM, and energy dispersive X-ray spectroscopy. Results revealed that the as-synthesized CuInS₂ colloid is in the tetragonal phase (size: 13–17 nm) and the AgInS₂ in the orthorhombic structure (size: 17±0.5 nm). A possible shape evolution and crystal growth mechanism has been suggested for the formation of pyramidal CuInS₂ and rectangular AgInS₂ colloids. Control experiments indicated that the morphology- and/or phase-change of CuInS₂ and orthorhombic AgInS₂ colloids are temperature- and/or time-dependent. CuInS₂ colloids absorb well in the range of visible light at room-temperature, indicating its potential application as a solar absorber. Two photoluminescence (PL) subbands at 1.938 and 2.384 eV in the PL spectra of CuInS₂ colloids revealed that the recombination of the closest and the second closest donor–acceptor pairs within the CuInS₂ lattice, in which the donor defect (Cu_i) occupies an interstitial position and the acceptor defect (V_In) resides at an adjacent cation site. In addition, the synthesis strategy developed in this study is convenient and inexpensive, and could also be used as a general process for the synthesis of other pure or doped ternary chalcogenides that require a controlled size (or shape). This process could be extended to the synthesis of other functional nanomaterials.