University of Mazandaran | Iran
Prof. Ali Bahari is a distinguished Professor of Nanotechnology in the Department of Solid-State Physics at the University of Mazandaran, Iran, and is globally recognized as part of the World’s Top 2% of Scientists by Stanford University. He earned his Ph.D. in Physics and Nanotechnology from Odense University (SDU), Denmark, where he focused on nanostructural properties of materials, growth, characterization, and applications. Over the years, Prof. Bahari has made remarkable contributions in quantum technologies, nanoelectronics, nanostructured materials, metamaterials, organic and polymer devices, cyborg technologies, cement-based composites, and clean energy production. His interdisciplinary research integrates nanotechnology, condensed matter physics, and material science, producing highly impactful innovations for sustainable development. Prof. Bahari has supervised numerous doctoral and master’s students, guided cutting-edge projects, and collaborated with international researchers to advance the understanding of material properties at the atomic and nanoscale level. He is an active reviewer for several high-impact journals and has presented his work at global conferences, strengthening the bridge between academia and industry. His outstanding contributions to nanoelectronics, perovskite optoelectronics, and metamaterials research have set new benchmarks for future studies. His work on magnetic nanostructures and electrocatalysis has wide-ranging applications in medicine, renewable energy, and sensor development, marking him as a leading figure in contemporary nanoscience.
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Featured Publications
The injection of Ag nanoparticles on surface of WO3 thin film: enhanced electrochromic coloration efficiency and switching response
Synthesis and tuning of gold nanorods with surface plasmon resonance
Experimental and theoretical studies of ordinary Portland cement composites contains nano LSCO perovskite with Fokker-Planck and chemical reaction equations
Structural and dielectric characteristic of povidone–silica nanocomposite films on the Si (n) substrate
Enhanced absorption performance of carbon nanostructure based metamaterials and tuning impedance matching behavior by an external AC electric field