International Journal of Engineering and Management Research
  • Year: 2026
  • Volume: 15
  • Issue: 3

Biogenesis and Characterization of Pilea-Microphylla Ferric Oxide Nanoparticles

  • Author:
  • D Gaikwad1, P Udekar2*, N Lohakare3, V Lad4, O Naik5, S Patil6
  • Total Page Count: 4
  • Page Number: 32 to 35

1Deepak Gaikwad, Department of Physics, KTSP Mandal’s KMC College, Khopoli, Maharashtra, India.

2Prathmesh Udekar, Department of Physics, Ramsheth Thakur College of Commerce and Science, Kharghar, Maharashtra, India.

3Neelam Lohakare, Department of Chemistry, Ramsheth Thakur College of Commerce and Science, Kharghar, Maharashtra, India.

4Vishwanath Lad, Department of Basic Sciences, Chhatrapati Shivaji Maharaj University, Panvel, Maharashtra, India.

5Omkar Naik, Department of Basic Sciences, Chhatrapati Shivaji Maharaj University, Panvel, Maharashtra, India.

6Sahil Patil, Mahatma Phule Arts Science and Commerce College, Panvel, Mumbai, Maharashtra, India.

*Corresponding Author Prathmesh Udekar, Department of Physics, Ramsheth Thakur College of Commerce and Science, Kharghar, Maharashtra, India. Email: prathmeshudekar@rtccs.edu.cin

Abstract

Nanotechnology involves the manipulation of materials at the nanoscale, enabling their application across fields such as environmental remediation, medicine, and engineering. However, conventional nanoparticle synthesis methods often rely on toxic reducing agents like sodium borohydride, posing environmental and health risks. This research focuses on the eco-friendly synthesis of ferric oxide nanoparticles (Fe2O3NPs) using the plant extract Pilea microphylla, a herb rich in bioactive phytochemicals such as quercetin, luteolin, and apigenin derivatives. These phytochemicals act as natural reducing and capping agents, eliminating the need for hazardous chemicals. In this study, Pilea microphylla was processed into an aqueous extract and used to synthesize Fe2O3NPs from ferric nitrate. The reaction mixture was stirred with NaOH and centrifuged to collect the nanoparticles, which were subsequently calcined at 300–400°C. The synthesized Fe2O3NPs were characterized using X-ray Diffraction (XRD) and Field Emission Scanning Electron Microscopy (FESEM) to confirm particle size and morphology. The results demonstrate that plant-based synthesis offers a scalable, cost-effective, and sustainable approach to nanoparticle production, with potential applications in wastewater treatment and environmental remediation.

Keywords

Pilea-Microphylla, Iron Nanoparticles, Green Synthesis, XRD, FE SEM