Best Researcher Award
| Zeinelabedin Mohamed | |
|---|---|
| Affiliation | Military University of Technology |
| Country | Poland |
| Scopus ID | 57473945000 |
| Documents | 9 |
| Citations | 46 |
| h-index | 5 |
| Subject Area | Materialis Engineering |
| Event | Research Data Analysis Awards |
| ORCID | 0000-0001-6050-0961 |
Zeinelabedin Mohamed
Military University of Technology
Zeinelabedin Mohamed is a researcher affiliated with the Military University of Technology in Poland, where his scholarly activities focus on materials engineering and related technological applications. His publication record, citation performance, and documented research outputs demonstrate active participation in advancing engineering knowledge through experimental and analytical investigations.[1]
Contents
Abstract
This article summarizes the academic profile of Zeinelabedin Mohamed, highlighting measurable research indicators, scholarly publications, and contributions within materials engineering. The profile reflects documented research productivity and recognized academic engagement supported by indexed publications and citation records.[1]
Keywords
Materials Engineering, Advanced Materials, Mechanical Engineering, Surface Engineering, Structural Materials, Scientific Research, Scopus Author, Engineering Innovation.
Introduction
Materials engineering supports innovation across aerospace, defense, manufacturing, and infrastructure by improving material performance and reliability. Researchers in this discipline combine experimentation with engineering analysis to develop practical scientific solutions that contribute to technological progress.[2]
Research Profile
According to indexed author information, Zeinelabedin Mohamed has published nine Scopus-indexed documents, received forty-six citations, and achieved an h-index of five. These indicators demonstrate sustained participation in peer-reviewed engineering research and scientific dissemination.[1]
Research Contributions
His investigations emphasize material characterization techniques that improve understanding of structural behavior under different operational conditions. These studies provide data supporting engineering design decisions and laboratory validation.The published research also explores engineering applications involving material performance, durability, and optimization. Such work contributes to evidence-based approaches for improving reliability in advanced engineering systems.
Publications
The research portfolio includes peer-reviewed journal publications indexed by Scopus that address topics in materials engineering and related technologies. Published articles contribute to scientific literature through experimental findings, analytical methodologies, and engineering evaluations.[3]
Research Impact
Citation metrics indicate that the published work has received scholarly attention within the engineering community. The combination of publications, citations, and an established h-index reflects measurable academic visibility and continued research engagement.[1]
Award Suitability
The documented publication record, citation performance, and participation in engineering research demonstrate qualifications commonly considered during academic recognition programs. Evaluation may include originality, publication quality, scientific impact, and continued contribution to the research community.[4]
Conclusion
Zeinelabedin Mohamed maintains an active academic profile in materials engineering supported by indexed publications and recognized citation metrics. His documented scholarly output represents continued engagement in engineering research and scientific communication within the international academic community.[5]
External Links
References
- Elsevier. (n.d.). Scopus author details: Zeinelabedin Mohamed, Author ID 57473945000.
https://www.scopus.com/authid/detail.uri?authorId=57473945000 - Mohamed, Z. A., & Norek, M. (2026). One-dimensional photonic crystal mirror heterostructure for ultra-high-Q optical refractive index sensing. Sensing and Imaging, 27(1), 64.
- Mohamed, Z. A., & Norek, M. (2026). Simulation study on optimizing spectral selectivity of thick PAA/Al bilayers for passive daytime radiative cooling. Solar Energy Materials and Solar Cells, 306, 114556.
http://link.springer.com/article/10.1007/s11220-026-00766-y - ORCID. Researcher Profile.
https://orcid.org/0000-0001-6050-0961 - Mohamed, Z. A. (2026). Design and investigation of a plasmonic metamaterial terahertz sensor for refractive index sensing. Optical and Quantum Electronics, 58(5), 188.
https://link.springer.com/article/10.1007/s11082-026-08744-0