Ln-CuPNFs

Materials

ref material size size err size unit size type size comment BET b nanozyme b 10n b unit specific act sa 10n sa unit comment
8214 1168 Ln-CuPNFs 70 50 μm SEM The micrographs given in Fig. 3 support that the petal density and the diameter of the flower increases from 20 to 120 μm. Fig. 2a–e gives a comparative analysis among the SEM micrographs of CuPNFs synthesized using different Ln derivatives. While the simple CuPNFs are of 25 μm in size, the average size of the NFs changes to 8.5 μm for Ln possessing the phenyl group (Fig. 2b), which suggests the marginal effect of the Ph-group as a glue to hold the flower-like morphology of copper phosphate. 54.98 Based on the BET analysis, the surface area for simple CuPNF given in Fig. 1d is 83.28 m2 g−1 while the organic derivatized ones exhibited 54.98, 51.88, 39.24, and 25.92 m2 g−1 for Ln-CuPNF (n = 1, 2, 3, 4), respectively.

Kinetics

ref material enzyme type substrate pH T km km err km 10n km unit vmax vmax err vmax 10n vmax unit kcat kcat err kcat 10n kcat unit kcat/km kcat/km 10n kcat/km unit comment

Applications

ref material application target method linear range linear ran unit LOD lod unit recovery comment

References

ref title DOI material type comment
4353 1168 Development and Demonstration of Functionalized Inorganic-Organic Hybrid Copper Phosphate Nanoflowers for Mimicking the Oxidative Reactions of Metalloenzymes by Working as a … https://doi.org/10.1039/D1TB00221J Composite Copper phosphate nanoflowers (CuPNFs) have been synthesized in the presence of different aromatic phenanthroline derivatives (Ln), leading to inorganic–organic hybrid materials (Ln-CuPNFs)