Ahmed Nabih Zaki Rashed | Solar Energy Technologies | Best Scholar Award

Published on by Green Energy Award

Best Scholar Award

Ahmed Nabih Zaki Rashed — Menoufiya University

Ahmed Nabih Zaki Rashed
Affiliation Menoufiya University
Country Egypt
Scopus ID 36118361900
Documents 402
Citations 13,219
h-index 65
Subject Area Solar Energy Technologies
Event World Green Energy Awards
ORCID 0000-0002-5338-1623

Ahmed Nabih Zaki Rashed is associated with Menoufiya University in Egypt and has contributed extensively to the field of solar energy technologies through multidisciplinary engineering research. His scholarly profile demonstrates sustained academic productivity, citation influence, and participation in renewable energy studies related to communication systems, optical technologies, and sustainable engineering developments.[1]

Abstract

Ahmed Nabih Zaki Rashed has established a recognized academic presence in solar energy technologies, optical communications, and sustainable engineering systems through a broad range of scientific publications and interdisciplinary investigations. His research activities include optical fiber communication, renewable energy integration, signal transmission technologies, and advanced photonic applications relevant to energy-efficient infrastructure development. The scholarly profile associated with his Scopus records indicates significant citation performance and international academic visibility. His contributions have supported scientific discussions surrounding sustainable technological innovation and engineering optimization. These achievements position him as a suitable candidate for recognition through the Best Scholar Award presented by the World Green Energy Awards.[1][2]

Keywords

Solar energy technologies, optical communication systems, renewable energy engineering, photonic networks, sustainable infrastructure, signal transmission, energy-efficient systems, optical fiber research, engineering innovation, green technology applications.

Introduction

The advancement of renewable energy systems increasingly depends on interdisciplinary engineering approaches capable of improving communication efficiency, energy transmission, and sustainable technological integration. Ahmed Nabih Zaki Rashed has contributed to these evolving scientific discussions through research focused on optical systems, photonic communication, and solar technology applications relevant to modern engineering infrastructure.[1]

Research Profile

The academic profile of Ahmed Nabih Zaki Rashed demonstrates substantial scholarly productivity with more than four hundred indexed documents and a strong citation record within Scopus databases. His research activities span optical communication engineering, photonic devices, renewable technologies, and signal processing applications connected to sustainable engineering systems and scientific innovation.[1]

Research Contributions

Ahmed Nabih Zaki Rashed has contributed to engineering research through investigations involving optical fiber systems, communication technologies, photonic network optimization, and sustainable electronic applications. His publications frequently address methods for improving data transmission efficiency, communication reliability, and renewable technology integration in engineering environments associated with energy-conscious technological development.

Publications

The publication record associated with Ahmed Nabih Zaki Rashed includes journal articles addressing optical transmission systems, renewable engineering technologies, and photonic applications. Several studies examine performance optimization, wavelength transmission, communication modeling, and engineering efficiency in sustainable systems, contributing to broader academic discussions concerning technological innovation and environmental sustainability.[3]

Research Impact

The research impact of Ahmed Nabih Zaki Rashed is reflected through citation metrics, interdisciplinary visibility, and continued academic engagement within engineering and renewable technology communities. His h-index and citation performance indicate sustained scholarly recognition, while his publications contribute to ongoing discussions involving communication technologies, energy systems, and scientific advancement.[1]

Award Suitability

Ahmed Nabih Zaki Rashed demonstrates qualifications consistent with the objectives of the Best Scholar Award presented by the World Green Energy Awards. His sustained research productivity, citation influence, and interdisciplinary engineering contributions support recognition for scholarly achievements connected to renewable energy technologies, communication engineering, and sustainable scientific development.[2]

Conclusion

The academic contributions of Ahmed Nabih Zaki Rashed illustrate active engagement in renewable energy engineering, optical technologies, and sustainable communication research. His publication history, citation metrics, and interdisciplinary scientific activities collectively indicate meaningful participation in engineering scholarship, supporting his recognition within international academic and renewable energy award platforms.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Ahmed Nabih Zaki Rashed, Author ID 36118361900. Scopus.https://www.scopus.com/authid/detail.uri?authorId=36118361900
  2. World Green Energy Awards. (n.d.). Best Scholar Award evaluation criteria and academic recognition standards.
    https://greenenergyaward.com/
  3. Parvin, T., Ahmed, K., Alatwi, A. M., & Rashed, A. N. Z. (2021). Differential optical absorption spectroscopy-based refractive index sensor for cancer cell detection. <i>Optical Review, 28</i>(1), 134–143.
    https://doi.org/10.1007/s10043-021-00644-w
  4. Inthiyaz, S., Altahan, B. R., Ahammad, S. H., Rajesh, V., Kalangi, R. R., Smirani, L. K., Hossain, M. A., & Rashed, A. N. Z. (2023). Skin disease detection using deep learning. Advances in Engineering Software, 175, 103361.
    https://doi.org/10.1016/j.advengsoft.2022.103361
  5. Polasi, P. K., Vellela, S. S., Narayana, J. L., Simon, J., Kapileswar, N., Prabu, R. T., & Rashed, A. N. Z. (2024). Data rates transmission, operation performance speed and figure of merit signature for various quadurature light sources under spectral and thermal effects. <i>Journal of Optics, 55</i>(4), 633–643.
    https://doi.org/10.1007/s12596-024-02032-4

Alexey Beskopylny | Green Technology | Best Researcher Award

Published on by Green Energy Award

Best Researcher Award

Alexey Beskopylny
Don State Technical University

Alexey Beskopylny
Affiliation Don State Technical University
Country Russia
Scopus ID 57212303470
Documents 207
Citations 2,630
h-index 26
Subject Area Green technology
Event World Green Energy Awards
ORCID 0000-0002-6173-9365

The Best Researcher Award recognizes distinguished scholarly achievements and sustained scientific contributions in the field of green technology and sustainable engineering. Alexey Beskopylny of Don State Technical University has established a significant academic profile through interdisciplinary research related to advanced construction materials, environmental sustainability, engineering systems, and innovative green technologies. His publication record, citation metrics, and research visibility demonstrate measurable influence within contemporary engineering and sustainability studies.[1]

Abstract

Alexey Beskopylny is recognized for scholarly contributions associated with sustainable engineering, construction technologies, and environmentally responsible materials research. His academic activities include publication development, interdisciplinary collaboration, and applied engineering investigations relevant to green technology innovation. The researcher has contributed to scientific discourse through peer-reviewed publications indexed in international databases, demonstrating consistent engagement with modern sustainability challenges and engineering optimization methods.[1][2]

Keywords

Green technology, sustainable engineering, environmental materials, structural engineering, construction innovation, energy-efficient systems, sustainable development, engineering research, advanced materials, academic excellence.

Introduction

The advancement of green technology has become increasingly important within modern engineering and environmental sciences. Researchers contributing to sustainable infrastructure, resource-efficient materials, and ecological engineering practices are central to contemporary scientific progress. Alexey Beskopylny has participated in research areas associated with construction engineering and sustainability-oriented technological development. His scholarly output reflects active involvement in scientific initiatives aimed at improving engineering performance while supporting environmentally conscious methodologies.[1]

Research Profile

Alexey Beskopylny is affiliated with Don State Technical University in Russia and maintains an established research presence within engineering and green technology studies. According to Scopus indexing data, the researcher has authored more than 200 scholarly documents and achieved over 2,600 citations, with an h-index of 26, indicating consistent citation activity across multiple publications.[1]

Research Contributions

The researcher has contributed to scientific studies involving sustainable construction technologies and advanced engineering materials. Several investigations address durability optimization, structural efficiency, and environmentally responsible design strategies intended to support modern sustainability goals.[4]

Publications

Selected publications and indexed research outputs associated with Alexey Beskopylny demonstrate sustained scholarly engagement in engineering and green technology disciplines.[4]

Research Impact

Citation metrics and publication indexing indicate measurable academic influence within engineering and sustainability research communities. The researcher’s h-index and citation record demonstrate that published works have contributed to ongoing scientific discussions in areas associated with green technology and applied engineering sciences.[1]

Award Suitability

Alexey Beskopylny demonstrates suitability for recognition through the World Green Energy Awards based on documented research productivity, international indexing visibility, interdisciplinary engineering contributions, and citation impact. His academic work aligns with themes related to sustainability, green technology innovation, and environmentally responsible engineering advancement.[3]

Conclusion

The academic profile of Alexey Beskopylny reflects sustained engagement with engineering research and sustainability-oriented technological development. Through publication activity, collaborative research, and measurable citation influence, the researcher has contributed to scientific discussions associated with green technology and advanced engineering systems. Recognition through the Best Researcher Award category within the World Green Energy Awards framework is supported by documented scholarly performance and relevance to contemporary sustainability objectives.[1][3]

References

  1. Elsevier. (n.d.). Scopus author details: Alexey Beskopylny, Author ID 57212303470. https://www.scopus.com/authid/detail.uri?authorId=57212303470
  2. ORCID. (n.d.). ORCID profile for Alexey Beskopylny.
    https://orcid.org/0000-0002-6173-9365
  3. World Green Energy Awards. (n.d.). Official award and recognition platform.
    https://greenenergyaward.com/
  4. Beskopylny, A. N., Stel’makh, S. A., Shcherban’, E. M., Mailyan, L. R., Meskhi, B., Razveeva, I., Chernil’nik, A., & Beskopylny, N. (2022). Concrete strength prediction using machine learning methods CatBoost, k-nearest neighbors, support vector regression. , 12(21), 10864.
    https://doi.org/10.3390/app122110864
  5. Özkılıç, Y. O., Karalar, M., Aksoylu, C., Beskopylny, A. N., Stel’makh, S. A., Shcherban, E. M., Qaidi, S., Pereira, I. da S. A., Monteiro, S. N., & Azevedo, A. R. G. (2023). Shear performance of reinforced expansive concrete beams utilizing aluminium waste. Journal of Materials Research and Technology, 24, 5433–5448. https://doi.org/10.1016/j.jmrt.2023.04.120