Abstract
Highly efficient fluorescent and biocompatible europium doped sodium zinc molybdate (NZMOE) nanoprobes were successfully synthesized via Polyol method. Non-radiative defect centres get reduced with Li+ co-doping in NZMOE nanoprobes. XRD spectra and Rietveld refinement confirmed successful incorporation of lithium ion and crystallinity was also improved with Li+ co-doping. The shape of phosphor is rod shaped, as determined by TEM. Significant enhancement in photoluminescence intensity was observed with 266, 395 and 465 nm excitations. Profound red emission was recorded for 5 at% Li+ co-doped NZMOE nanoprobes with 266 nm excitation. It shows high asymmetry ratio (~15), color purity (94.90%) and good quantum efficiency (~70%). Judd Ofelt parameters have been calculated to measure intensity parameters and radiative transition rates. In order to measure biocompatibility of the nanoprobes, cytotoxicity assays were performed with HePG2 cells. The fluorescence emitted from phosphor material treated HePG2 cells was also measured by Laser Scanning Confocal Microscopy. The bright red fluorescence in HePG2 cells treated with very low concentration (20 μg/ml) of phosphor material indicates that it could be a promising phosphor for biological detection or bio-imaging.
Highlights
Among various oxides, ZnMoO4 has aroused great interest due to its excellent PL emission properties, photo-catalytic activity, improved photo-stability and electronic conductivity[20,21,22]
The data clearly shows that atomic positions of Zn and Na are fixed and there is minor shift in atomic positions of Mo metal observed with Li+ co-doping in NZMOE
Li+ co-doped NZMOE having rod-like structures have successfully been synthesized by Polyol method
Summary
Neha Jain[1], Ruchi Paroha[2], Rajan K. The fluorescence emitted from phosphor material treated HePG2 cells was measured by Laser Scanning Confocal Microscopy. The bright red fluorescence in HePG2 cells treated with very low concentration (20 μg/ml) of phosphor material indicates that it could be a promising phosphor for biological detection or bio-imaging. If Eu3+ activated sodium zinc molybdate is biocompatible it can be a promising phosphor for bio-imaging purpose. Xie et al reported improved PL emission by Eu3+activated ZnMoO4 with charge compensation by alkali metals and found prominent emission for Li+ ion co-doped phosphor[28] The reason behind it is that Li+ ion has smaller atomic radius, it enters into the crystal and affects crystal environment as well as the site symmetry of Eu3+ ion. The data was analysedfor statistical significance by using Student’s t-test and p < 0.05 was considered as statistically significant
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