Abstract
The main features of the “green” synthesis of metallic nanoparticles (MNPs) by the sonoelectrochemical methods are manufacturability, environmental friendliness, and the possibility of controlling the geometry of the forming particles. The electrochemical reduction technique allows efficiently designing the metal nanoparticles and provides the control of the content of components of bimetallic nanoparticles, as well as minimizing the number of precursors in working solutions. Due to the generation of turbulence, microjets, and shock waves, ultrasound increases mass transfer and formation of radicals in aqueous solutions and, accordingly, accelerates the processes of nucleation and growth of MNPs. Therefore, this hybrid method, which combines electrolysis and ultrasound, has attracted the interest of researchers in the last two decades as one of the most promising techniques. The present work presents a short analysis of the reference literature on sonoelectrochemical synthesis of metallic and bimetallic nanoparticles. The main factors influencing the geometry of nanoparticles and their size distribution are analyzed. The use of pulsed ultrasound and pulsed current supply during sonoelectrochemical synthesis is especially effective in designing MNPs. Emphasis is placed on the role of surfactants in the formation of MNPs and sacrificial anodes in providing the algorithm: “anodic dissolution-electrochemical reduction of metal-nucleation and formation of МNPs.” It is noted that ultrasound allows synthesizing the MNPs and M1M2NPs during the galvanic replacement, and an analogy of the formation of nanoparticles by sonogalvanic replacement and sonoelectrochemical method is shown.
Highlights
Metal nanoparticles are widely used in biomedicine [1,2,3,4,5], biosensors [4, 6, 7], catalysis [1, 8], and other fields. e nanoparticles of noble metals are the most studied in terms of the synthesis methods, as well as physicochemical and functional properties
Nanoparticles and nanoclusters of noble metals are effective in detecting the biological agents and play a very important role in biomedicine. us, in [6], the advantages of plasmonic AgNPs, AuNPs, and PtNPs for the colorimetric sensing applications in drugs assays in pharmaceutical and biological samples are described. e use of gold nanoparticles in the chemiluminescence technique showed a high sensitivity for the detection of biological agents [7]
In the triad, the method of synthesis ⟶ geometry metallic nanoparticles (MNPs) ⟶ functional properties, the first component is decisive. e processes of obtaining of MNPs and M1M2NPs should correspond to the following basic modern criteria: (1) the control of the geometry and the composition of nanoparticles; (2) “green” synthesis; and (3) manufacturability
Summary
Metal nanoparticles are widely used in biomedicine [1,2,3,4,5], biosensors [4, 6, 7], catalysis [1, 8], and other fields. e nanoparticles of noble metals are the most studied in terms of the synthesis methods, as well as physicochemical and functional properties. Using the AuNPs [3] and PtNCs [4] for the treatment of cancer and bacterial diseases gave encouraging results in the last decade. AuNPs and PtNCs are considered as a new effective class of chemotherapeutics in the treatment of hematopoietic, lung, and hepatocellular malignant tumors. Nanoparticles and nanoclusters of noble metals are effective in detecting the biological agents and play a very important role in biomedicine. Us, in [6], the advantages of plasmonic AgNPs, AuNPs, and PtNPs for the colorimetric sensing applications in drugs assays in pharmaceutical and biological samples are described. E use of gold nanoparticles in the chemiluminescence technique showed a high sensitivity for the detection of biological agents [7] Nanoparticles and nanoclusters of noble metals are effective in detecting the biological agents and play a very important role in biomedicine. us, in [6], the advantages of plasmonic AgNPs, AuNPs, and PtNPs for the colorimetric sensing applications in drugs assays in pharmaceutical and biological samples are described. e use of gold nanoparticles in the chemiluminescence technique showed a high sensitivity for the detection of biological agents [7]
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