期刊
NANOSCALE
卷 13, 期 41, 页码 17521-17529出版社
ROYAL SOC CHEMISTRY
DOI: 10.1039/d1nr05767g
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- ETH Zurich
- RAEng/Levelhume Trust
Mesocrystals are superstructures of crystallographically aligned nanoparticles displaying advanced morphologies and properties beyond those from size and shape alone. The first synthesis of Cu3N mesocrystals with structure-directing agents and subtle tuning of reaction parameters is reported. Detailed structural characterizations reveal non-classical crystallization of Cu3N mesocrystals and variations in sizes and morphologies traced back to distinct attachment scenarios of subunits. Conversion processes of Cu3N mesocrystals into multicomponent/heterostructured Cu3N-Cu2O mesocrystals and subsequently into Cu2O nanocages involve a two-step mechanism driven by nanoscale Kirkendall effect.
Mesocrystals are superstructures of crystallographically aligned nanoparticles and are a rapidly emerging class of crystalline materials displaying sophisticated morphologies and properties, beyond those originating from size and shape of nanoparticles alone. This study reports the first synthesis of Cu3N mesocrystals employing structure-directing agents with a subtle tuning of the reaction parameters. Detailed structural characterizations carried out with a combination of transmission electron microscopy techniques (HRTEM, HAADF-STEM-EXDS) reveal that Cu3N mesocrystals form by non-classical crystallization, and variations in their sizes and morphologies are traced back to distinct attachment scenarios of corresponding mesocrystal subunits. In the presence of oleylamine, the mesocrystal subunits in the early reaction stages prealign in a crystallographic fashion and afterwards grow into the final mesocrystals, while in the presence of hexadecylamine the subunits come into contact through misaligned attachment, and subsequently, to some degree, realign in crystallographic register. Upon prolonged heating both types of mesocrystals undergo chemical conversion processes resulting in structural and morphological changes. A two-step mechanism of chemical conversion is proposed, involving Cu3N decomposition and anion exchange driven by the nanoscale Kirkendall effect, resulting first in multicomponent/heterostructured Cu3N-Cu2O mesocrystals, which subsequently convert into Cu2O nanocages. It is anticipated that combining nanostructured Cu3N and Cu2O in a mesocrystalline and hollow morphology will provide a platform to expand their application potential.
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