Nanocrystal engineering: Unraveling bioactivities and augmented photocatalytic degradation of ZnO and Cr-doped ZnO via green and chemical synthesis routes

Herein, we focused on the combined investigation of physicochemical traits and multifunctional bioactivity of ZnO and Cr-doped ZnO NPs synthesized by chemical and green synthesis methods. The green synthesis was accomplished by utilizing Azadirachta Indica leaf extracts which include the phytochemicals azadirachtin and nimbolide function as prominent therapeutic agents in diagnosis. The XRD and TEM analysis evidences all the prepared NPs exhibit hexagonal wurtzite structure, and the change in crystallinity of ZnO NPs with Cr substi-tution has been examined. The optical properties show that Cr inclusion effectively changes the optical band gap of pure ZnO NPs, confirming the quantum confinement effect. The synthesized NPs were employed to investigate photocatalytic degradation of Rhodamine B (Rh B) dye in an aqueous environment under UV irradiation. The Rh-B dye effectively degraded within 180 min in the presence of synthesized nano catalyst at room temperature. Further, the synthesized NPs were subjected to investigate their bio-potency for microbicidal and cytotoxicity properties. The biosynthesized Cr-ZnO NPs exhibit significant cytotoxicity against A-549 lung cancer cells with the lowest IC50 value (21.79 mu g/ml) and also demonstrate good antioxidant activity with the highest percentage of inhibition 81.23 % as measured by the DPPH scavenging assay in contrast to other NPs. In addition, the chemically synthesized Cr-ZnO NPs found the highest inhibition activity (90.78 %) for antidiabetic efficiency of Alpha-amylase enzyme assay and also shows significant antibacterial activities with a higher zone of inhibition (17 mm) against gram-positive Bacillus cereus over other samples. Thus, this study highlights ZnO NPs versatile attributes, paving the way for promising biomedical and environmental uses.