Mohammad Ali Nasiri | Sustainable Energy Materials | Research Excellence Award

Published on by Metallurgical Engineering

Research Excellence Award

Mohammad Ali Nasiri
University of Valencia, Spain

Mohammad Ali Nasiri
Affiliation University of Valencia
Country Spain
Scopus ID 57226509306
Documents 14
Citations 232
h-index 6
Subject Area Sustainable Energy Materials
Event Metallurgical Engineering Awards
ORCID 0000-0003-1376-3288

Mohammad Ali Nasiri is a researcher specializing in sustainable energy materials, nanostructured systems, thermoelectric technologies, energy storage materials, and advanced functional devices. His academic activities encompass materials engineering, nanotechnology, clean energy solutions, and the development of environmentally responsible technologies for future energy applications. The Research Excellence Award recognizes distinguished scholarly achievement, sustained research productivity, and contributions to scientific advancement through innovative investigation and interdisciplinary collaboration.[1]

Abstract

Mohammad Ali Nasiri has established a research profile centered on nanostructured materials, thermoelectric systems, sustainable energy technologies, energy storage materials, and advanced optoelectronic devices. His work integrates materials science, nanotechnology, and energy engineering to develop innovative solutions for energy conversion, harvesting, storage, and sensing applications. Through peer-reviewed publications, international collaborations, and contributions to sustainable material development, he has supported advancements in environmentally responsible energy technologies and functional material systems.[2]

Keywords

Sustainable Energy Materials; Thermoelectric Systems; Nanostructured Materials; Energy Storage Technologies; MXenes; Quantum Dots; Perovskites; Nanofabrication; Functional Materials; Optoelectronic Devices.

Introduction

Research in sustainable energy technologies increasingly relies on advanced materials capable of improving energy efficiency, storage performance, and environmental sustainability. Mohammad Ali Nasiri’s academic background includes doctoral training in nanoscience and nanotechnology together with multidisciplinary expertise spanning nanomaterials science and aerospace engineering. His work contributes to emerging technologies designed to address challenges associated with clean energy generation, thermal management, and advanced electronic systems.[1]

Research Profile

As a Postdoctoral Researcher at the Institute of Materials Science (ICMUV), University of Valencia, Mohammad Ali Nasiri conducts research focused on the synthesis, characterization, and application of advanced materials for sustainable energy systems. His experience includes cleanroom microfabrication, nanofabrication technologies, thermal transport studies, and the development of functional materials for energy harvesting and storage applications. His scholarly record includes peer-reviewed publications, international collaborations, and participation in multiple research projects related to advanced energy technologies.[2]

Research Contributions

Mohammad Ali Nasiri’s contributions include research on ionic thermoelectric systems, conductive polymer nanocomposites, MXene-based materials, ultrathin metallic electrodes, lignin-derived sustainable materials, and advanced energy-storage architectures. His investigations emphasize scalable fabrication approaches and environmentally responsible material selection to improve performance in energy conversion and storage devices. These efforts support broader scientific objectives associated with renewable energy adoption and sustainable technological development.[3]

Publications

The researcher has authored publications in internationally recognized journals covering materials science, energy storage, functional materials, and applied physics. His publication portfolio demonstrates interdisciplinary engagement across nanotechnology, energy systems, and sustainable materials research.[4]

  • Advanced Functional Materials
  • Chemical Science
  • Advanced Optical Materials
  • Applied Physics Reviews
  • Journal of Energy Storage

Research Impact

Mohammad Ali Nasiri’s research is reflected through scholarly citations, collaborative projects, peer-review activities, and contributions to the advancement of sustainable energy materials. His work supports ongoing efforts to improve energy efficiency and develop renewable-material-based technologies capable of addressing future environmental and industrial challenges. The integration of sustainable feedstocks with advanced nanomaterials represents a notable aspect of his research direction.[3]

Award Suitability

The Research Excellence Award recognizes individuals who demonstrate sustained scholarly productivity, innovative research contributions, and measurable influence within their fields. Mohammad Ali Nasiri’s record of research activity, international collaboration, publication output, and commitment to sustainable energy technologies aligns with the objectives of the award. His multidisciplinary expertise contributes to advancing scientific understanding while supporting practical applications in energy conversion, storage, and advanced materials engineering.[5]

Conclusion

Mohammad Ali Nasiri’s academic and research achievements illustrate a consistent commitment to scientific investigation in sustainable energy materials and nanotechnology. Through interdisciplinary research, publication activity, collaborative engagement, and contributions to advanced material development, he has supported the advancement of knowledge relevant to contemporary energy and environmental challenges. His profile represents the qualities commonly associated with research excellence within the international scientific community.

References

  1. Elsevier. (n.d.). Scopus author details: Mohammad Ali Nasiri, Author ID 57226509306. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=57226509306
  2. Nasiri, M.A., et. al. (2024). Recent advances in ionic thermoelectric systems and theoretical modelling. Chemical Science.
    https://pubs.rsc.org/en/content/articlehtml/2018/dg/d4sc04158e
  3. Nasiri, M.A., et. al. (2026). Carbonization-Enhanced Bio-Based Multilayer Electrodes for Sustainable Energy Storage. Journal of Energy Storage.
    https://www.sciencedirect.com/science/article/pii/S2352152X26026046
  4. Nasiri, M.A., et. al. (2024). Ultrathin transparent nickel electrodes for thermoelectric applications.
    https://advanced.onlinelibrary.wiley.com/doi/full/10.1002/admi.202300705
  5. Nasiri, M.A., et. al. (2025). Lignin-Derived ionic hydrogels for thermoelectric energy harvesting. ACS Applied Polymer Materials
    https://pubs.acs.org/doi/full/10.1021/acsapm.4c03816

Fahanwi Asabuwa Ngwabebhoh | Sustainable Materials | Research Excellence Award

Published on by Metallurgical Engineering

Assist. Prof. Dr. Fahanwi Asabuwa Ngwabebhoh | Sustainable Materials | Research Excellence Award

Research Scientist at Kocaeli University | Turkey

Assist. Prof. Dr. Fahanwi Asabuwa Ngwabebhoh is a materials and polymer scientist recognized for advancing functional biomaterials, nanocomposites, and environmentally responsive polymers through research that integrates synthesis, structural modification, and performance optimization. His scientific work centers on bioinspired hydrogels, nanocellulose-derived systems, electroactive polymer composites, and sustainable biopolymer materials designed for applications in adsorption, drug delivery, wound healing, environmental remediation, energy storage, and biosensing. With 1,385 citations, 48 published documents, and a Scopus h-index of 19, he is widely acknowledged for producing high-impact research that bridges fundamental materials chemistry with practical technological solutions. His investigations have yielded important contributions to controlled drug delivery systems, injectable and self-crosslinking hydrogels, microbial cellulose biocomposites, conductive polymer–based electrodes for supercapacitors, photodegradation materials, and agro-waste-derived sustainable composites. He has also developed optimized nanostructured adsorbents and membrane systems for emerging pollutant removal, applying advanced modeling tools such as response surface methodology and kinetic–isotherm analysis to enhance material efficiency and predict functional behavior. His research on nitrogen-doped cellulose gels, enzymatically crosslinked hydrogels, and biodegradable nanofibrous scaffolds has been influential in both environmental and biomedical materials science. Dr. Ngwabebhoh’s work demonstrates strong interdisciplinary depth, combining polymer chemistry, nanotechnology, materials characterization, and applied engineering principles to generate innovation-driven scientific output. His publication profile and research achievements reflect impactful contributions that support sustainable technologies, advanced biomaterials, and green material design, establishing him as a leading researcher suited for recognition through the Research Excellence Award.

Profiles : Scopus | ORCID | Google Scholar

Featured Publications

Ngwabebhoh, F. A., Gazi, M., & Oladipo, A. A. (2016). Adsorptive removal of multi-azo dye from aqueous phase using a semi-IPN superabsorbent chitosan-starch hydrogel. Chemical Engineering Research and Design. Citation: 173

Ngwabebhoh, F. A., Erdagi, S. I., & Yildiz, U. (2018). Pickering emulsions stabilized nanocellulosic-based nanoparticles for coumarin and curcumin nanoencapsulations: In vitro release, anticancer and antimicrobial activities. Carbohydrate Polymers. Citation: 165

Erdagi, S. I., Ngwabebhoh, F. A., & Yildiz, U. (2020). Genipin crosslinked gelatin-diosgenin-nanocellulose hydrogels for potential wound dressing and healing applications. International Journal of Biological Macromolecules. Citation: 142

Nguyen, T. H., Fei, H., Sapurina, I., Ngwabebhoh, F. A., Bubulinca, C., Munster, L., & others. (2021). Electrochemical performance of composites made of rGO with Zn-MOF and PANI as electrodes for supercapacitors. Electrochimica Acta. Citation: 131

Ngwabebhoh, F. A., Zandraa, O., Patwa, R., Saha, N., Capáková, Z., & Saha, P. (2021). Self-crosslinked chitosan/dialdehyde xanthan gum blended hypromellose hydrogel for the controlled delivery of ampicillin, minocycline and rifampicin. International Journal of Biological Macromolecules. Citation: 103