Table 1.
A summary of recent advances in microemulsion-based synthesis of Re nanoparticles (NPs). DDAB—dimethyl dioctyl ammonium bromide; DDAI—dimethyl dioctyl ammonium iodide; AOT—dioctylsulfosuccinate sodium.
| Metal NP Composition | Microemulsion Type | Surfactant | Particle Size | Highlight(s) of Synthetic Method | Ref |
|---|---|---|---|---|---|
| Re NPs | Reverse microemulsion (a/o) | DDAB or DDAI | 2.2 nm | Useful for synthesizing oxidation-sensitive NPs. Needs very low temperature |
[72] |
| Re NPs | Reverse microemulsion | AOT | 1–18 nm (depends on the synthesis conditions) | Control of the particle size with varying γ-irradiation doses. | [73,74] |
| Re/Re oxide NPs | Reverse microemulsion | AOT | 0.7–1.4 nm | Obtained very small sized particles with a narrow size distribution but metal NPs oxidation state was not studied. Reverse trend observed for W factor effect. |
[75] |
| Pt-Re bimetallic NPs | Reverse microemulsion | Triton X-100 | 1.8–2.05 nm | Small bimetallic NPs obtained, Used a very low W value (=0.3) |
[77] |
| Re6 cluster@SiO2 NPs | Reverse microemulsion | Brij 30 | 30 nm | NPs kept their luminescence properties in aqueous solutions (potential for biological applications) (need to form multinuclear Re cluster at high temperatures first) |
[81] |
| Re sulfide NPs | Reverse microemulsion | NP5/NP10 or NP10/Triton X-45 | - | Introduced a novel high-throughput microemulsion synthesis device | [82] |