Table 1.
A summary of various methods for the synthesis of nanomaterials.
| Nanomaterials synthetis method | Mechanisms involved | Advantages and Disadvantages | Ref. |
|---|---|---|---|
| Mechanical milling | Impact of the ball-powder-ball collision on powder particles which undergo deformations and/or fractures, thus achieving size reduction and/or alloying | More economical for large scale processes; irregular particle shape and crystal defects are induced, creating a metastable composition | [34] |
| Lithography | Transfer of nanopatterns with templates for masked lithography and direct transfer for maskless approach. Another approach (nanosphere lithography) is through the dispersion of spherical colloids to form a colloidal crystal mask for selective patterning and allow deposition of desired materials | Can be top-down or bottom-up, generally high resolution of shape and position of NPs, yet production cost is high with low throughput | [36], [58], [59] |
| Laser-ablation | Removal of the surface atom from a solid target with a laser energy source. Nucleation of evaporated species and subsequent growth into NPs | A green method for controlled and high purity NP synthesis without using toxic chemicals, yet low production rates | [39] |
| Chemical etching | Chiseling of nanostructures out of solid surfaces through the use of etchants such as strong acids and/or alkalis | High etching rate and low equipment cost; difficulty in achieving smaller features and reliance on hazardous materials | [40], [60] |
| Sol-gel | Chemical method involving hydrolysis of precursors, polycondensation of molecules to form a network of colloids and subsequent aging, drying and calcination that controls the size and morphology of NPs | High control over NPs texture, achievable at a lower temperature; however, the processing time is long | [44] |
| Chemical vapour deposition | Vaccum deposition of vaporised precursors on heated substrates forming 2D NPs | High purity and homogeneity of the product. The process is limited by extremely high-temperature demand, and by-products are toxic gases | [46] |
| Biosynthesis | Use of microorganisms as bioagents, the enzymatic activities foster reduction and stabilization of NPs | Green and environmentally friendly approach, yet poor control over NPs size and many other mechanisms are still poorly understood | [49] |
| Pyrolysis | Thermal decomposition of precursors and subsequent formation and growth of particles by gas-phase chemical reactions and coagulation | High product yield and cost-effective but extreme synthesis conditions | [35] |