Abstract
Binding energies of different nitrile solvents and their utilization for CuCN formation were investigated through quantum chemical calculations. A pulsed laser ablation in liquid (PLAL) method for CuCN synthesis was developed herein. Initially, the interaction between the pulsed laser and the Cu-target generated Cu-ions and electrons at the point of contact. The laser beam also exhibited sufficient energy to dissociate the bonds of the respective solvents. In the case of acetonitrile, the oxidized Cu-ions bonded with CN− to produce CuCN with a cube-like surface structure. Other nitrile solvents generated spherically-shaped Cu@graphitic carbon (Cu@GC) nanoparticles. Thus, the production of CuCN was favorable only in acetonitrile due to the availability of the cyano group immediately after the fragmentation of acetonitrile (CH3+ and CN−) under PLAL. Conversely, propionitrile and butyronitrile released large amounts of hydrocarbons, which deposited on Cu NPs surface to form GC layers. Following the encapsulation of Cu NPs with carbon shells, further interaction with the cyano group was not possible. Subsequently, theoretical study on the binding energies of nitrile solvents was confirmed by highly correlated basic sets of B3LYP and MP2 which results were consistent with the experimental outcomes. The findings obtained herein could be utilized for the development of novel metal–polymer materials.
Highlights
The production of metal cyanides has attracted considerable interest due to their commercial applications in different industries
In addition to CuCN, a trace amount of pure metallic Cu NPs was present in the sample synthesized in acetonitrile, which was confirmed by weak diffraction peaks
These bonds underwent dissociation during pulsed laser ablation in liquid (PLAL), releasing a large amount of alkyl carbons, which further deposited on the surface of Cu NPs to form graphitic carbon (GC) layers
Summary
The production of metal cyanides has attracted considerable interest due to their commercial applications in different industries. During PLAL in various nitrile solvents, such as acetonitrile, propionitrile, and butyronitrile, the optimum laser wavelength was adjusted to 355, 532, and 1064 nm, respectively.
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