Table 1.
Deposition of nanomaterials on ceramic substrates.
| Application | Technique | Nanomaterial | Matrix | Year | Reference |
|---|---|---|---|---|---|
| Effect on structural and optical properties (With increasing film thickness, the dielectric properties, absorption coefficient, and band gap energy have increased) | Vertical deposition angle and high vacuum using electron gun evaporation method | Tantalum oxidenanolayers | Glass substrate | 2021 | [25] |
| Low-cost methodology | Spray deposition | Graphene nanoplatelets | Carbon fiber–reinforced polymer | 2020 | [26] |
| Low-cost and easy way for the preparation of 1D ZnO nanostructures | Electrochemical deposition | ZnO nanorod arrays | ITO glass substrates | 2015 | [27] |
| Antibacterial properties | Tollen’s reaction | Silver nanoparticles | Inorganic and organic substrate surfaces (Metallic, polymeric, ceramic) | 2004 | [28] |
| Sensing and catalysis | Electroless deposition | Au nanoparticles | Different substrates | 2020 | [29] |
| Modify physical properties | Physical vapor deposition | Titanium nanolayers | Glass substrates | 2013 | [36] |
| Low cost to provide reliable bond strength | In situ deposition | Nano-Silica | Yttria–Tetragonal Zirconia Polycrystal (Y–TZP) | 2015 | [37] |