Statistical analysis (ANOVA, p < 0.05) showed significant inhibition for AgNP‑treated discs compared with the negative control. 5.1 Reaction Mechanism The phenolic compounds (e.g., catechins) in green‑tea act as electron donors , reducing Ag⁺ → Ag⁰ while being oxidised to quinones. Simultaneously, the same molecules adsorb onto nascent AgNP surfaces, providing a steric and electrostatic barrier that prevents uncontrolled growth and aggregation. The alkaline pH (≈ 8) deprotonates phenolic –OH groups, enhancing their nucleophilicity and thus the reduction rate. 5.2 Influence of Parameters | Parameter | Effect on Nanoparticle Characteristics | |-----------|------------------------------------------| | Extract‑to‑Ag ratio | Higher extract content yields smaller, more uniformly capped particles (excess capping agents limit growth). | | Temperature | Elevated temperature accelerates reduction but can broaden size distribution if too high (> 80 °C). | | pH | pH 8 balances phenolate formation and Ag⁺ stability; at pH 10, rapid reduction leads to premature nucleation and broader size distribution. | | Reaction time | 30 min is sufficient for complete reduction; extending to 60 min does not significantly alter size but may cause slight agglomeration. | 5.3 Comparison with Conventional Methods | Feature | Green Synthesis (Zoikhem Lab 26) | Conventional NaBH₄ Reduction | |---------|-----------------------------------|-------------------------------| | Reducing agent | Plant phenolics (non‑toxic) | NaBH₄ (hazardous) | | By‑products | Benign quinones, water | Borates, possible metal residues | | Energy demand | Moderate heating (70 °C) | Often ice‑cold conditions | | Particle size control | Tunable via extract concentration | Typically requires strict stoichiometry | | Cost | Low (tea leaves) | Higher (chemical reagents) | | Environmental impact | Minimal waste, biodegradable | Significant chemical waste |
(A detailed laboratory report and discussion for undergraduate/graduate chemistry students) 1. Introduction Nanoparticles of silver (AgNPs) are prized for their antimicrobial, catalytic, and optical properties. Conventional synthesis routes often rely on hazardous reducing agents (e.g., NaBH₄, hydrazine) and generate toxic by‑products. In recent years, green synthesis —the use of biological materials such as plant extracts, microorganisms, or biopolymers as reducing and capping agents—has emerged as a sustainable alternative. Zoikhem Lab 26