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The ever-growing energy, clean water, and manufactured products' demand worldwide is enlarging environmental pollution; therefore, the development of green remediation technologies is very urgent. Recently, green synthesis has emerged as an alternative to chemical and physical conventional nanoparticle production methods that offer environmentally benign pathways depending on plant extracts, microbial culture, or bio-waste as reducing and stabilizing agents under mild reaction conditions. This review critically looks at the recent advances in the green biosynthesis of some metal-oxide nanoparticles. Special attention is given to the preparation parameter-extract concentration, solution pH, and reaction time that dictates nucleation, growth, particle size, morphology, and colloidal stability. The resultant nanomaterials evidence multifunctional properties, including photocatalytic activity, optical properties, adsorption capacity, antioxidant behavior, and antibacterial effects, hence finding broad application in wastewater treatment, energy, and biomedical systems. Long-term stability, sensitivity to environmental fluctuations, and reproducibility in realistic scenarios are still major obstacles to be overcome despite encouraging laboratory-scale performance. In order to bridge these gaps, the present review sets out a parameter-structure-performance framework associating the conditions of synthesis with functional efficiency and potential scalability. Insights from this work will help guide the rationale behind the design, standardization, and future translation of green-synthesized nanomaterials for practical applications in environmental, energy, and biomedical areas.
Abubakar et al. (Tue,) studied this question.