Kwaghgba Elijah Gbabe | Technology Scientists Innovations | Nanotechnology Innovation Award

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Dr. Kwaghgba Elijah Gbabe | Technology Scientists Innovations | Nanotechnology Innovation Award

Senior Research Officer at Nigerian Stored Products Research Institute, Nigeria

Dr. Kwaghgba Elijah Gbabe is a Senior Research Officer at the Nigerian Stored Products Research Institute, Ilorin, Nigeria. With over 9 years of experience, he specializes in food processing, postharvest technology, and agricultural nanotechnology. His research focuses on prolonging the shelf-life of perishable crops using eco-friendly nano-fibre systems and enhancing food quality through advanced preservation methods. Dr. Gbabe earned his M.Eng. in Agricultural and Environmental Engineering from the University of Agriculture, Makurdi, and is pursuing his Ph.D. in Food Processing and Technology at Benue State University. He has conducted international research at the Centre for Agricultural Nanotechnology, TNAU, India, and published multiple peer-reviewed articles. He also contributes actively to training farmers, artisans, and technical personnel. Dr. Gbabe’s work bridges the gap between sustainability and innovation in food preservation, making him a standout candidate in the technological innovation domain.

Author Profile

Strengths for the Award

  1. Strong Foundation in Agricultural Nanotechnology
    Dr. Gbabe has established a niche in the application of nanotechnology to agricultural and food preservation challenges. His Ph.D. research focuses on developing an electrospun hexanal nano-fibre matrix—a cutting-edge innovation aimed at extending the shelf-life of perishable fruits like banana, mango, and tomato.

  2. International Exposure and Training
    He completed a prestigious internship at the Centre for Agricultural Nanotechnology, TNAU, India, where he conducted nanotoxicity, biosafety, and electrospinning-based preservation studies—highlighting both cross-cultural collaboration and technological advancement.

  3. Peer-Reviewed Nanotech Publications
    Dr. Gbabe has authored several relevant papers in reputed journals:

    • Journal of the Indian Chemical Society (2025): On hexanal nano-fiber matrices for tomato preservation.

    • IJETT (2025): Development of nano-fiber matrices for mango shelf-life extension.

    • Nano Plus (2023): On banana fruit preservation using electrospun nanotechnology.
      These works clearly demonstrate applied innovation, rigorous experimentation, and measurable societal impact in reducing food loss.

  4. Technical Skills Aligned with Nanotech Innovation
    Proficient in electrospinning, FTIR, GC-MS, SEM & TEM, and statistical software (R, SPSS), showing an interdisciplinary approach involving both materials science and food technology.

  5. Leadership in National Innovation Projects
    As a Senior Research Officer at the Nigerian Stored Products Research Institute, he actively leads R&D on postharvest loss reduction and food quality enhancement technologies—bridging innovation with policy and field deployment.

🎓 Education 

Dr. Gbabe holds a Master of Engineering in Agricultural and Environmental Engineering (2019) from the University of Agriculture, Makurdi, Nigeria. His thesis focused on eco-building materials using rice husk and sawdust, reflecting an early interest in sustainable engineering. He is currently completing his Ph.D. in Food Processing and Technology (2020–2025) at Benue State University, Makurdi. His doctoral research is centered on the development of electrospun hexanal nano-fibre matrices aimed at extending the shelf-life of tropical fruits like bananas, mangoes, and tomatoes. He is a registered engineer with COREN Nigeria and a member of the Nigerian Institution of Agricultural Engineers. In 2023, he was a research intern at the Centre for Agricultural Nanotechnology, TNAU, India, where he gained hands-on experience in nanotoxicology, electrospinning, and biosafety. His academic journey reflects a strong foundation in multidisciplinary innovation and food systems sustainability.

🔬 Research Focus on Technology Scientists Innovations

Dr. Gbabe’s research is rooted in postharvest technology, agricultural nanotechnology, and food quality preservation. His core contributions lie in the design and development of nanostructured packaging and preservation systems using biodegradable hexanal-based nano-fibers, created via electrospinning. These innovations target tropical fruit shelf-life extension and nutrient retention during storage. He is equally involved in evaluating postharvest handling systems, including the construction of solar dryers and inert-atmosphere silos. His projects align closely with SDG 2 (Zero Hunger) and SDG 12 (Sustainable Consumption & Production). Dr. Gbabe also explores sustainable materials (like rice husk-based eco-panels), biosafety assessments in nanoformulations, and pest management using botanicals. His work is highly applied, integrating field deployment, engineering fabrication, and local capacity building—benefiting smallholder farmers and food industries across West Africa.

📚 Publication Top Notes

  1. Gbabe et al. (2025)
    Effect of Hexanal Nano-fiber Matrix on Quality Parameters of Tomato Fruits during Storage
    Journal: Journal of the Indian Chemical Society
    Summary: Demonstrates improved shelf-life and reduced spoilage in tomato fruits using hexanal-loaded nano-fiber packaging developed via electrospinning.
    DOI: 10.1016/j.jics.2025.101912

  2. Gbabe et al. (2025)
    Development of Novel Hexanal Nano-fibre Matrix by Electrospinning for Shelf-life Extension of Mango Fruits
    Journal: International Journal of Engineering Trends and Technology
    Summary: Describes the fabrication and optimization of mango-preserving nano-matrices, with a focus on temperature resilience and biodegradability.
    DOI: 10.14445/22315381/IJETT-V73I3P132

  3. Chukwu et al. (2025)
    Implication of Different Storage Techniques on Physical Attributes of African Okra
    Journal: IJABR
    Summary: Assesses how traditional vs. improved storage impacts okra firmness, color, and moisture, with relevance to rural postharvest systems.

  4. Idris et al. (2024)
    Maize grains milling efficiency: A performance analysis of a hammer mill
    Journal: International Journal of Agronomy and Agricultural Research
    Summary: Compares efficiency metrics of hammer mills to suggest design improvements for rural grain processing.
    Link

  5. Adeniyi et al. (2024)
    Insecticidal and Toxicity Studies of Heliotropium Indicum Leaf Extracts
    Journal: Journal of Exposure Toxicology
    Summary: Investigates natural pest control agents for stored grain insects—highlighting bio-safety and efficacy.

  6. Oyewole et al. (2020)
    Commercial Utilization of Inert Atmosphere Silo for Maize Storage
    Journal: IOP Conf. Series: Earth and Environmental Science
    Summary: Presents the benefits of modified atmosphere storage in reducing maize spoilage.

Conclusion

Dr. Kwaghgba Elijah Gbabe is highly suitable for the Research for Nanotechnology Innovation Award. His work represents a strong blend of scientific depth, practical relevance, and innovation in nanotechnology applications for agriculture and food preservation. With further strides in international publication, commercialization, and cross-sectoral collaborations, Dr. Gbabe has the potential to become a leading figure in agricultural nanotech innovation across Africa and globally.

Kishwar Ali | Nanophotonics | Best Paper Award

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Mr. Kishwar Ali | Nanophotonics | Best Paper Award

PhD Student, University of L’Aquila, Italy.

Kishwar Ali is a doctoral researcher at the University of L’Aquila, Italy, specializing in nanophotonics and advanced electromagnetic modeling. His core expertise lies in investigating the Goos–Hänchen shift (GHS) in novel metamaterial configurations using fractional calculus and time-space modulated media. Through strong collaborations with international experts and rigorous theoretical contributions, he has developed new paradigms for controlling light reflection and propagation in hyperbolic and zero-index materials. His vision blends deep physics with real-world applications, such as hyperlensing and photonic sensors. Kishwar is an active member of the IEEE Antennas and Propagation Society and is committed to pushing the boundaries of optical theory toward practical innovation.

📌Author Profile

🎓 Education 

Kishwar Ali is currently pursuing his PhD at the University of L’Aquila in Italy. His doctoral training emphasizes advanced computational modeling and electromagnetic field theory applied to metamaterials and nanophotonics. His research bridges theoretical optics, mathematical modeling in fractional dimensions, and practical application in layered photonic structures. His academic background integrates foundational knowledge in applied physics with specialized training in electromagnetic theory and materials science. During his doctoral journey, Kishwar has been mentored by leading scientists and has contributed to multiple high-impact publications, enhancing his research rigor and interdisciplinary insights.

💼 Experience

As a PhD student, Kishwar Ali has co-authored four peer-reviewed publications, tackling complex optical phenomena such as the Goos–Hänchen shift and its manipulation in fractional and anisotropic media. He is actively engaged in a major project on spatiotemporal band engineering in photonic crystals. His research experience includes theoretical model development, analytical derivations, simulation implementation, and result validation. Kishwar collaborates with international researchers from Italy and Pakistan and contributes significantly to manuscript drafting, mathematical modeling, and peer communication. Though early in his professional journey, his impactful publications and innovative focus have already made notable impressions in the nanophotonics domain.

🔬 Research Focus 

Kishwar Ali’s research is focused on light–matter interaction in metamaterials and spatiotemporal optical media, particularly the Goos–Hänchen shift and its enhancement or suppression in engineered systems. His interests lie in understanding how electromagnetic fields behave in complex layered structures, including near-zero-index materials, fractional spaces, and hyperbolic graphene composites. He is currently working on periodic space-time modulation to explore new forms of bandgap engineering, with potential implications in light steering, hyperlensing, and optical sensing technologies. Kishwar integrates analytical modeling, numerical simulation, and physics-driven intuition to develop concepts applicable to quantum optics, nanophotonics, and optical cloaking devices.

📚 Publication Top Notes

  1. Enhanced Control of the Goos–Hänchen Shift at Graphene-Hyperbolic Boron Nitride Multilayer Hyper Crystal
    Optics & Laser Technology, 191, 113390, 2025
    Authors: K Ali, F Ferranti, F Frezza, G Antonini
    Summary: This study presents a novel way to manipulate the Goos–Hänchen shift using hybrid graphene-hBN structures, enabling improved beam control. Applications include optical sensors and super-resolution imaging.

  2. Rest-Frame Quasi-Static Analysis for a Rotating Core-Shell Structure in a Fractional Dimensional Space
    JOSA B, Vol. 42(3), pp. 611-620, 2025
    Authors: S Parveen, K Ali, A Shahzad, QA Naqvi
    Summary: Investigates light interaction in a rotating nanostructure within a fractional-dimensional framework. This work adds a new perspective to electromagnetic modeling in non-integer geometries.

  3. Magnetic and Fractional Parametric Control of Goos-Hänchen Shifts in the Anisotropic Yttrium-Iron-Garnet Film Surrounded by Isotropic Fractal Dielectric Half-Spaces
    Physics Letters A, 453, 128496, 2022
    Authors: K Ali, WI Waseer, QA Naqvi
    Summary: Explores how magnetic fields and fractional-order modeling can be used to fine-tune light shifts in complex magnetic-dielectric environments.

  4. Goos–Hanchen-Effect for Near-Zero-Index Metamaterials Excited by Fractional Dual Fields
    Optik, 243, 167501, 2021
    Authors: K Ali, AA Syed, WI Waseer, QA Naqvi
    Summary: Analyzes how fractional dual fields affect the Goos–Hänchen effect in zero-index metamaterials. This is foundational for developing cloaking and advanced light-guiding technologies.

Conclusion

Kishwar Ali demonstrates a strong theoretical foundation and thematic consistency in studying light–matter interactions through the lens of Goos–Hänchen shifts in engineered materials. His recent 2025 work on graphene-hyperbolic boron nitride multilayer crystals stands out as a highlight for its innovation and potential application.