Irina Yanina | Upconversion | Women Researcher Award

Women Researcher Award

Researcher: Irina Yanina
Institution: National Research Saratov State University

                     IrinYanina
Affiliation National Research Saratov State University
Country Russia
Scopus ID 22952614500
Documents 92
Citations 621
h-index 13
Subject Area Upconversion
Event International Material Scientist Awards

Irina Yanina is a researcher affiliated with the National Research Saratov State University, Russia. Her scholarly activities focus on optical biomedical technologies, tissue optics, photonics, and upconversion materials for biomedical imaging and diagnostics. With a substantial publication record, consistent citation performance, and recognized contributions to optical science, her profile demonstrates sustained academic productivity and interdisciplinary collaboration suitable for international scientific recognition.[1]

Abstract

Irina Yanina has established an internationally recognized research profile through investigations in biomedical optics, photonics, tissue imaging, laser diagnostics, and optical spectroscopy with particular emphasis on upconversion technologies. Her work contributes to improved understanding of light interaction with biological tissues, enabling advances in medical diagnostics, therapeutic monitoring, and non-invasive imaging methodologies. Supported by ninety-two indexed publications, six hundred twenty-one citations, and an h-index of thirteen, her research reflects sustained scholarly productivity, interdisciplinary collaboration, and measurable scientific influence within materials science, biomedical engineering, and applied optical research communities.

Keywords

Upconversion research integrates biomedical optics, photonics, optical imaging, laser diagnostics, and tissue optics to advance non-invasive medical technologies and functional optical materials. These interdisciplinary innovations improve imaging sensitivity, diagnostic precision, and therapeutic monitoring while supporting developments in nanophotonics, biomedical engineering, and next-generation healthcare applications through enhanced light–matter interactions.

Introduction

Modern biomedical optics integrates material science, photonics, and medical engineering to improve disease diagnosis and therapeutic monitoring. Irina Yanina has contributed to this interdisciplinary field through investigations involving optical properties of biological tissues, imaging systems, and advanced photonic materials that support enhanced diagnostic accuracy and innovative healthcare technologies.

Research Profile

The research profile demonstrates consistent academic productivity across biomedical optics, spectroscopy, tissue diagnostics, and optical material applications. Her publication portfolio indicates long-term engagement with internationally indexed journals while citation metrics reflect continuing scholarly relevance and recognition by researchers working in photonics, imaging science, and healthcare technology.

Research Contributions

Her scientific contributions include investigations of optical tissue characterization, laser interaction with biological materials, fluorescence imaging, optical coherence methods, and upconversion nanoparticles for biomedical applications. These studies support improved diagnostic precision while expanding scientific understanding of photonic materials used in non-invasive medical technologies.

Publications

The documented publication record comprises ninety-two Scopus-indexed scholarly works published in reputable international journals. These publications encompass biomedical optics, laser medicine, optical diagnostics, spectroscopy, and advanced photonic materials, demonstrating sustained research productivity and active participation within the global scientific community.[1]

Research Impact

Research impact is reflected through six hundred twenty-one citations and an h-index of thirteen, indicating consistent utilization of published findings by the international research community. These bibliometric indicators demonstrate sustained academic influence and meaningful contributions to biomedical imaging, photonic materials, and optical diagnostic methodologies.[2]

Award Suitability

The academic profile aligns well with the objectives of the Women Researcher Award presented during the International Material Scientist Awards. Sustained publication activity, measurable citation performance, interdisciplinary research, and internationally recognized scientific contributions collectively demonstrate professional excellence deserving consideration for distinguished academic recognition.[3]

Conclusion

Irina Yanina represents an accomplished researcher whose work advances biomedical optics and upconversion-related technologies through rigorous scientific investigation. Her publication achievements, citation record, and interdisciplinary collaborations illustrate sustained research excellence, making her academic profile appropriate for international recognition within the materials science and biomedical research communities.[4]

References

  1. Elsevier. (n.d.). Scopus author details: Irina Yanina, Author ID 22952614500. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=22952614500
  2. Crossref. (2023). Biomedical optics and photonics research.
    https://doi.org/10.1016/j.jphotobiol.2023.112650
  3. International Material Scientist Awards. (2026). Women Researcher Award nomination information.
    https://materialscientists.com/
  4. Yanina, I., & colleagues. (2026). Biophysical alterations of the stratum corneum induced by optical clearing agents: Implications for efficiency and safety optimization. Skin Pharmacology and Physiology. Advance online publication.
    https://doi.org/10.1159/000550614

Seon-Bong Lee | Powder Metallurgy | Innovative Research Award

Innovative Research Award

Seon-Bong Lee
Affiliation Keimyung University
Country South Korea
Scopus ID 15837361800
Documents 56
Citations 373
h-index 11
Subject Area Powder Metallurgy
Event International Material Scientist Awards
ORCID 0000-0002-8355-1216

Seon-Bong Lee

Institution: Keimyung University, South Korea

Seon-Bong Lee is a researcher affiliated with Keimyung University whose scholarly activities primarily focus on powder metallurgy and materials science. His publication record, citation profile, and scientific contributions indicate sustained engagement in materials processing, metallic powders, sintering technologies, and engineering applications associated with advanced materials research.[1]

Abstract

This academic recognition article summarizes the research achievements and scientific profile of Seon-Bong Lee. The evaluation considers scholarly productivity, citation influence, subject expertise, and contributions to powder metallurgy. The available bibliometric indicators demonstrate sustained participation in materials science research and support recognition within the framework of the Innovative Research Award.[1]

Keywords

Powder Metallurgy, Materials Science, Sintering Technology, Metallic Materials, Advanced Materials, Engineering Materials, Research Impact, Scientific Publications.

Introduction

Powder metallurgy has become an essential discipline in modern materials engineering owing to its role in producing advanced components with controlled microstructures and mechanical properties. Researchers working in this field contribute to industrial manufacturing, energy applications, transportation systems, and emerging engineering technologies. The academic activities of Seon-Bong Lee align with these developments through contributions to materials processing and metallurgical research.[2]

Research Profile

The research profile of Seon-Bong Lee includes 56 indexed documents, 373 citations, and an h-index of 11. These indicators demonstrate measurable scholarly influence and continued participation in scientific publishing. His work primarily addresses powder metallurgy, material processing, and engineering applications relevant to advanced manufacturing technologies.[1]

  • Affiliation: Keimyung University.
  • Country: South Korea.
  • Research area: Powder Metallurgy.
  • Indexed documents: 56.
  • Citation count: 373.
  • h-index: 11.

Research Contributions

The scientific contributions of Seon-Bong Lee include investigations related to powder processing, sintering behavior, material characterization, and performance optimization of engineering materials. These studies support the development of reliable manufacturing methods and contribute to understanding the relationship between processing conditions and material properties.[2]

  • Development of powder processing methodologies.
  • Investigation of sintering mechanisms.
  • Characterization of engineering materials.
  • Evaluation of material properties and performance.
  • Contribution to metallurgical engineering research.

Publications

The publication record demonstrates consistent scientific productivity within materials science and powder metallurgy. Articles indexed in international databases contribute to scholarly visibility and citation impact.[1]

  1. Research articles addressing powder metallurgy applications.
  2. Studies involving metallic material processing technologies.
  3. Investigations of microstructural characterization methods.
  4. Engineering materials performance evaluations.

Representative DOI resources relevant to powder metallurgy include studies published within metallurgical and materials engineering literature.[3]

Research Impact

Citation metrics provide evidence of the academic visibility of the researcher’s contributions. The citation count and h-index indicate that multiple publications have achieved recognition within the scientific community. Such bibliometric indicators are commonly employed to evaluate research influence and scholarly productivity.[1]

Award Suitability

The available research indicators support consideration of Seon-Bong Lee for the Innovative Research Award presented during the International Material Scientist Awards. The combination of publication productivity, citation performance, subject specialization, and continued scientific engagement demonstrates suitability for academic recognition within materials science and powder metallurgy.[1]

Conclusion

Seon-Bong Lee has established a measurable research profile within powder metallurgy and materials science. His scholarly output, citation impact, and research contributions provide a foundation for professional recognition through the Innovative Research Award. The available academic indicators demonstrate continued participation in scientific advancement and materials engineering research.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Seon-Bong Lee, Author ID 15837361800. Scopus. https://www.scopus.com/authid/detail.uri?authorId=15837361800
  2. Effect of Load Partitioning Under Different Pressing Temperature Conditions During 2P1A Compaction on the Densification Behavior and Electromagnetic Properties of Fe–5.0 wt.%Si SMC Core. https://www.mdpi.com/2075-4701/16/6/669
  3. Effect of MoS2 and Graphite Lubricant Contents on the Mechanical Properties of Fe–5.0 wt.%Si Soft Magnetic Composites. https://www.mdpi.com/1996-1944/19/12/2649

 

Jason Robinson | Superconductivity | Best Researcher Award

Best Researcher Award

Jason Robinson
University of Cambridge

Jason Robinson
Affiliation University of Cambridge
Country United Kingdom
Scopus ID 15046973600
Documents 131
Citations 5,604
h-index 39
Subject Area Superconductivity
Event International Material Scientist Awards

Jason Robinson of the University of Cambridge, United Kingdom. His research activities in superconductivity have contributed to developments in condensed matter physics, quantum materials, and superconducting spintronics. Bibliometric indicators demonstrate substantial scientific productivity and international research influence, making his academic profile highly relevant to recognition within the International Material Scientist Awards program.[1]

Abstract

This article evaluates the academic profile of Jason Robinson using bibliometric indicators, publication records, and scientific contributions within the field of superconductivity. The available evidence indicates substantial scholarly productivity and international scientific influence. The researcher demonstrates sustained contributions to superconducting materials and related physical sciences, supporting recognition under the Best Researcher Award category.[1]

Keywords

Best Researcher Award; Jason Robinson; Superconductivity; Quantum Materials; Scientific Impact; Condensed Matter Physics; Citation Analysis; International Material Scientist Awards.

Introduction

Scientific awards recognize researchers whose work significantly advances knowledge and innovation. The Best Researcher Award emphasizes publication quality, scientific influence, and sustained academic excellence. Jason Robinson’s research in superconductivity and advanced materials represents a substantial contribution to contemporary physical sciences and materials research.[2]

Research Profile

Jason Robinson is affiliated with the University of Cambridge and has established a strong international research profile. According to Scopus records, the researcher has published 131 indexed documents, accumulated 5,604 citations, and achieved an h-index of 39. These indicators demonstrate substantial research productivity and sustained academic influence.[1]

  • Research specialization in superconductivity.
  • Extensive international publication record.
  • Strong citation performance.
  • Contributions to quantum and superconducting materials research.

Research Contributions

The research contributions of Jason Robinson encompass superconductivity, quantum materials, and superconducting spintronics. His work has supported advances in understanding magnetic interactions within superconducting systems and has contributed to emerging technologies involving superconducting devices and materials.[3]

  • Development of superconducting materials research.
  • Contributions to superconducting spintronics.
  • Publication of high-impact scientific studies.
  • Influence on condensed matter physics research.

Publications

The publication portfolio includes numerous articles published in internationally recognized scientific journals. These publications contribute to superconductivity, condensed matter physics, and materials science literature and have received substantial scholarly attention.[1]

  • Indexed documents: 131.
  • Total citations: 5,604.
  • h-index: 39.

Research Impact

The citation performance of Jason Robinson indicates significant scientific influence within superconductivity and materials research. The h-index and citation count demonstrate continued utilization of his published work by the international scientific community. Such indicators are commonly employed in evaluating research visibility and academic impact.[2]

Award Suitability

The research achievements, publication productivity, and measurable citation impact of Jason Robinson strongly support consideration for the Best Researcher Award. His contributions to superconductivity and materials science align with the objectives of the International Material Scientist Awards and demonstrate sustained academic excellence.[4]

Conclusion

Jason Robinson has established an internationally recognized research profile characterized by substantial publication output, significant citation impact, and influential contributions to superconductivity research. The available bibliometric indicators and scientific achievements support recognition within academic award frameworks emphasizing excellence in research and innovation.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Jason Robinson, Author ID 15046973600. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=15046973600
  2. Roadmap on nanoscale superconductivity for quantum technologies.
    https://iopscience.iop.org/article/10.1088/1361-6668/ae3030/meta
  3. A Tribute to John Clarke, Michel Devoret and John Martinis for their Experiments on Quantum Tunneling and Energy Level Quantization in a Superconducting Macroscopic Circuit, Nobel Prize for Physics in 2025
    https://link.springer.com/article/10.1007/s10948-025-07101-8
  4. Realisation of de Gennes’ absolute superconducting switch with a heavy metal interface
    https://www.nature.com/articles/s41467-025-61267-2

Prof. Dr. Jean Sire Armand Eyebe Fouda | Materials Science | Research Excellence Award

Prof. Dr. Jean Sire Armand Eyebe Fouda | Materials Science | Research Excellence Award

University of Yaoundé I | Cameroon

Prof. Dr. Jean Sire Armand Eyebe Fouda is a distinguished scholar whose research spans materials science, systems theory, and complex dynamical systems, with a strong interdisciplinary orientation linking physics, engineering, and data-driven analysis. He is a Full Professor at the University of Yaoundé I, where he has established a research profile characterized by methodological innovation and cross-disciplinary impact. His work focuses on nonlinear dynamics and statistical physics, with particular emphasis on nonlinear time-series analysis and its application to complex material, biological, and environmental systems. Prof. Fouda has developed advanced algorithms and analytical tools that enable deeper understanding of complex signals arising from real-world systems, including biological data, climate-related processes, and mechatronic systems with intricate dynamics. His research contributions extend to embedded and intelligent systems, where he has been involved in the design and implementation of mechatronic and control systems that integrate materials behavior with automation and robotics principles. In parallel, he has contributed to innovative approaches in secure data processing through the development of pseudo-random number generation and encryption techniques relevant to multimedia and digital systems. Prof. Fouda is actively engaged in international scientific collaboration, working closely with research groups in Europe on dynamical system analysis, climate-related modeling, and complex systems theory. He is a member of leading professional societies in computational physics, biological physics, and climate physics, reflecting the breadth of his scientific engagement. In addition to his research activities, he is committed to academic leadership, graduate supervision, and the dissemination of scientific knowledge through teaching and scholarly communication. Prof. Dr. Jean Sire Armand Eyebe Fouda’s work demonstrates intellectual depth, interdisciplinary reach, and sustained research excellence, making him a highly deserving recipient of the Research Excellence Award.

Citation Metrics (Scopus)

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456

Documents
37

h-index
13

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Prof. Shuzheng Shi | Materials Science | Research Excellence Award

Prof. Shuzheng Shi | Materials Science | Research Excellence Award

Hebei University of Architecture | China

Prof. Shuzheng Shi is a distinguished academic and researcher in materials science, with a strong interdisciplinary profile spanning micro/nano sensors, microsystems, and sustainable materials innovation. He serves as a Professor in the School of Mechanical Engineering at Hebei University of Architecture, where he is actively involved in research leadership, teaching, and postgraduate supervision. Prof. Shi’s work focuses on the design and development of advanced micro- and nanoscale sensor systems for environmental, industrial, and smart manufacturing applications, addressing critical challenges in sensitivity, reliability, and system integration. In parallel, he has made significant contributions to the high-value utilization of bulk waste resources, transforming industrial and solid wastes into functional composite materials and energy-related materials that support circular economy and sustainability goals. His research combines materials science, instrumentation engineering, and applied mechanics, enabling the translation of fundamental concepts into practical technologies with real industrial relevance. Prof. Shi has led and contributed to numerous nationally supported and industry-oriented research projects, demonstrating strong capabilities in project coordination, innovation management, and technology transfer. His inventive output includes a substantial portfolio of patented technologies that reflect his commitment to applied research and industrial deployment. In addition to his scientific achievements, Prof. Shi actively contributes to the academic community through professional society membership, interdisciplinary collaboration, and mentorship of graduate students, many of whom are engaged in advanced materials and sensor research. His work has supported collaborations with leading universities and research institutions, strengthening links between academia and industry. Through his sustained contributions to sensor technology, sustainable materials development, and applied research innovation, Prof. Shuzheng Shi has established a strong reputation in materials science and is a highly deserving recipient of the Research Excellence Award.

Citation Metrics (Scopus)

350
250
50
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Citations
310

Documents
18

h-index
7

Citations

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Dr. Shin Young Park | Materials Science | Research Excellence Award

Dr. Shin Young Park | Materials Science | Research Excellence Award

Yonsei University College of Medicine | South Korea

Dr. Shin Young Park is an accomplished researcher whose work reflects a strong interdisciplinary integration of materials science, biomedical engineering, and clinical innovation, making her a compelling recipient of the Research Excellence Award. As a Clinical Assistant Professor in Emergency Medicine at Yonsei University College of Medicine, she brings a unique materials-oriented perspective to healthcare research, focusing on how material properties, biological interfaces, and physiological responses interact in high-stress medical environments. Her research interests encompass biomedical materials, biophysical indicators, and data-driven evaluation of material–tissue interactions relevant to trauma care, critical illness, and emergency diagnostics. Dr. Park has contributed to impactful peer-reviewed studies that explore biochemical markers, physiological indices, and system-level responses, offering insights that support the development of advanced diagnostic tools and clinically relevant material-based solutions. Her work demonstrates a strong emphasis on translational research, where scientific rigor is paired with practical application to improve patient outcomes and healthcare efficiency. In addition to her research achievements, she is actively engaged in medical education and mentorship, contributing to the training of future clinicians and researchers through teaching, supervision, and collaborative scholarship. Dr. Park’s interdisciplinary approach allows her to bridge materials science concepts with clinical data analysis, fostering innovation at the interface of science and medicine. Her dedication to research excellence, methodological precision, and interdisciplinary collaboration positions her as a valuable contributor to modern materials science applications in healthcare. Through sustained academic commitment and impactful scientific inquiry, Dr. Shin Young Park exemplifies the qualities recognized by the Research Excellence Award.

Citation Metrics (Scopus)

20
10
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2

Documents
2

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1

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Documents

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Mr. Sumit Hassan Eshan | Materials Science | Research Excellence Award

Mr. Sumit Hassan Eshan | Materials Science | Research Excellence Award

Contessa Solutions and Consultants Ltd | Bangladesh

Mr. Sumit Hassan Eshan is a dynamic early-career researcher whose multidisciplinary work spans materials science, smart antennas, photonics, wireless power transfer, and next-generation communication technologies. Alongside his role as a Lead Technical Engineer in Microsoft and Cyber Security at Contessa Solutions and Consultants Ltd., he has built a strong scientific profile through consistent research productivity, publishing in reputable international journals and IEEE conferences, including work that has been featured on the front cover of a high-ranking journal. His portfolio comprises innovative research on graphene-based antennas, terahertz devices for 6G applications, nanomaterial-enhanced patch antennas for biomedical diagnostics, and wireless power transfer systems, reflecting his ability to merge materials science with applied electromagnetics. He has contributed to the academic community as a peer reviewer for multiple international journals, demonstrating his growing recognition as a knowledgeable evaluator in electrical, electronic, and materials-related fields. Mr. Eshan’s expertise includes advanced modeling, antenna simulation using CST Studio Suite, electronic system design, nano-enhanced device development, and multidisciplinary engineering problem-solving. His previous research projects explore cutting-edge topics such as terahertz aeronautical antennas, multilayer carbon-nanotube sensors, perovskite-based solar cell transport layers, and biomedical detection systems. In addition to his academic achievements, he has completed diverse industrial and R&D roles, contributing to cloud solutions, cybersecurity infrastructures, antenna development, robotics projects, and technical team leadership. His strong combination of research excellence, technological innovation, and cross-domain engineering capability highlights his potential to advance impactful material-based, communication-driven, and biomedical sensing technologies. Mr. Sumit Hassan Eshan’s achievements, versatility, and dedication position him as a highly deserving nominee for the Research Excellence Award.

Citation Metrics (Scopus)

60
40
20
0

Citations
55

Documents
10

h-index
5

Citations

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Featured Publications


Enhanced Wireless Power Transfer System Using Integrated RF Amplification
– Results in Engineering, 2025

TI Anowar, RR Hasan, SH Eshan, M Foysal


Skin Tumor, Lipoma and Cyst Detection by Graphene Based On-Body Patch Antenna in L Band
– 2025 4th International Conference on Robotics, Electrical and Signal Engineering

SH Eshan, RR Hasan, M Farukuzzaman, R Basak, MS Hossen, R Rumky, …

Tungsten disulfide based wearable antenna in terahertz band for sixth generation applications
– TELKOMNIKA Telecommunication, Computing, Electronics and Control, 2024

A Roy, MR Bhuiyan, MA Islam, P Saha, SH Eshan, RR Hasan, R Basak


Spin Coated Multi-Walled Carbon Nanotube Patch Antenna for Breast Cancer Detection (Adv. Mater. Technol. 24/2023)
– Advanced Materials Technologies, 2023

RR Hasan, J Jasmine, AM Saleque, SH Eshan, RTH Tusher, S Zabin, …


Graphene based terahertz patch antenna for breast tumor detection
– TELKOMNIKA Telecommunication, Computing, Electronics and Control, 2024

L Moni, MSR Zishan, SH Eshan, RR Hasan

Dr. Yong Li | Materials Science | Research Excellence Award

Dr. Yong Li | Materials Science | Research Excellence Award

Shaanxi Normal University | China

Dr. Yong Li is an accomplished materials scientist whose rapidly growing research profile has positioned him as a leading contributor to next-generation photovoltaic technologies. With a strong academic foundation and a deep specialization in metal halide perovskite solar cells, his work spans defect passivation, interface engineering, crystallization control, and long-term device stability, enabling significant advancements in highly efficient and durable solar energy systems. Dr. Li has authored 52 scientific documents, demonstrating impressive productivity and a commitment to cutting-edge inquiry, and his research impact is reflected in 2,851 citations accumulated across 2,412 citing documents, supported further by a robust h-index of 29, highlighting both the depth and consistency of his scientific influence. His contributions focus on understanding the intricate interplay between precursor chemistry, molecular interactions, and interfacial processes, leading to innovative strategies for suppressing recombination, enhancing charge transport, and stabilizing perovskite layers under real-world conditions. Dr. Li’s work integrates experimental insight with advanced analytical techniques, offering design principles for scalable, low-cost solar modules and contributing to the global pursuit of sustainable and clean energy technologies. His portfolio includes impactful publications in SCI-indexed journals, collaborative initiatives with leading research groups, and involvement in strategically important research projects that address efficiency bottlenecks and operational reliability in modern solar cell architectures. Beyond fundamental research, he is committed to developing practical pathways for technology translation, bridging laboratory innovation with industrial relevance. Through his scholarly excellence, strong citation metrics, and growing international visibility, Dr. Li continues to shape the future of materials science and photovoltaic engineering, representing a new generation of researchers driving impactful solutions in renewable energy and contributing substantially to the advancement of high-performance solar materials.

Profiles: Scopus | Orcid

Featured Publications

Zheng, C., He, Y., Li, Y., Gao, A., Liu, Z., Chen, L., Wang, D., & Liu, S. (Frank). (2025). Oxidation stability of perovskite solar cells reinforced by punicalagin to resist UV damage. Advanced Functional Materials.

Li, Y., Dong, L., Cai, Y., Li, Y., Xu, D., Lei, H., Li, N., Fan, Z., Tan, J., Sun, R., Wang, B., Gong, J., Lin, Z., Guo, K., He, X., & Liu, Z.  (2025). Meticulous design of high-polarity interface material for FACsPbI₃ perovskite solar cells with efficiency of 26.47%. Angewandte Chemie International Edition, 64(26), e202504902.

Zhao, W., Lin, H., Li, Y., Wang, D., Wang, J., Liu, Z., Yuan, N., Ding, J., & Wang, Q. (2022). Symmetrical acceptor–donor–acceptor molecule as a versatile defect passivation agent toward efficient FA₀.₈₅MA₀.₁₅PbI₃ perovskite solar cells. Advanced Functional Materials, 32(19), 2112032.

Liu, B., Zhou, Q., Li, Y., Chen, Y., He, D., Ma, D., Han, X., Li, R., Yang, K., Yang, Y., Lu, S., Ren, X., Zhang, Z., Ding, L., Feng, J., Yi, J., & Che, J.  (2024). Polydentate ligand reinforced chelating to stabilize buried interface toward high-performance perovskite solar cells. Angewandte Chemie International Edition, 136(8), e202317185.

Wu, M., Wang, H., Li, Y., Chen, R., Zhou, H., Yang, S., Xu, D., Li, K., An, Z., Liu, S. (Frank)., & Liu, Z. (2023). Crystallization regulation by self-assembling liquid crystal template enables efficient and stable perovskite solar cells. Angewandte Chemie International Edition, 62(52), e202313472.

Mr. Sanjay Belowar | Materials Science | Science Visionary Award

Mr. Sanjay Belowar | Materials Science | Science Visionary Award

BGMEA University of Fashion and Technology | Bangladesh

Mr. Sanjay Belowar is an emerging materials and organic chemistry researcher from Bangladesh, currently pursuing his Ph.D. in Material Chemistry at the Bangladesh University of Engineering and Technology (BUET) and serving as a Research Instructor in Chemistry at BGMEA University of Fashion and Technology. With strong expertise in organic synthesis, computational chemistry, molecular modeling, and sustainable textile chemical technologies, he has developed an impactful academic profile dedicated to advancing eco-friendly and biocompatible dye systems for industrial application. Mr. Belowar has contributed significantly to research in azo dye synthesis, DFT-based quantum chemical simulation, HOMO–LUMO analysis, antimicrobial materials, and bio-based textile processing, integrating both experimental and theoretical approaches. His scientific output includes 5 peer-reviewed documents, which have received 13 citations across 12 international scholarly documents, establishing an h-index of 2, signaling steadily growing research visibility and influence. His published work appears in high-quality journals such as Dyes and Pigments, Environmental Science and Pollution Research, Waste and Biomass Valorization, and BUFT Journal of Fashion & Technology, contributing to sustainable coloration chemistry, natural dye mordants, biomass-derived chemical materials, and computationally predicted dye–substrate interactions. In addition to research accomplishments, Mr. Belowar plays an active academic role through undergraduate supervision, laboratory mentoring, scientific writing, and collaborative project involvement, including government-funded research focused on green chemistry and environmentally responsible textile production. His technical skills include FT-IR, NMR, UV-Vis spectroscopy, ADMET screening, molecular docking, and Gaussian computational packages, complemented by experience working in synthetic chemistry laboratories and process-oriented industrial training. His research contributions support cleaner manufacturing processes, circular economy principles, and reduced reliance on hazardous chemical dyes, positioning him as a promising scientist contributing to global sustainable material technologies. Dedicated, innovative, and academically driven, Mr. Sanjay Belowar continues to advance the future of environmentally conscious chemical research and industrial application.

Profiles: Scopus | Orcid | Google Scholar

Featured Publications

Islam, S., Jalil, M. A., Belowar, S., Saeed, M. A., Hossain, S., Rahamatolla, M., & Ali, S. (2025). Role of mordants in natural fabric dyeing and their environmental impacts. Environmental Science and Pollution Research, 32(2), 452–468.

Belowar, S., Rahamatolla, M., Islam, S., Jalil, M. A., Hossain, S., Saeed, M. A., … (2024). Design, synthesis, and characterization of a novel pH-responsive azo dye incorporating a 1,3,4-thiadiazole ring for advanced textile applications. Dyes and Pigments, 231, 112410.

Belowar, S., Shetu, F. K., Hossain, M. T., Das, S., Jalil, M. A., Rahamatolla, M., … (2025). Sustainable azo dye synthesis from expired paracetamol: Structural characterization, computational insights, and textile application. Dyes and Pigments, 113099.

Saeed, M. A., Islam, S., Jalil, M. A., Hossain, S., Belowar, S., Akter, F., … (2025). Sustainable utilization of Cyanodon dactylon biomass for cellulose derivatives and biofilm production. Waste and Biomass Valorization, 1–16.

Islam, S., Belowar, S., Das, S., Rahamatolla, M., & Datta, S. C. (2025). Chemistry of natural and synthetic dye materials with metal mordants in various fabrics for sustainable textile applications: A comprehensive review. Environmental Science and Pollution Research, 1–30.

Islam, S., Jalil, M. A., Motaleb, K. Z. M. A., Saeed, M. A., Belowar, S., Rahamatolla, M., … (2025). Toward a greener fabric: Innovations in natural dyes and biomordants for sustainable textile applications. Sustainability & Circularity NOW, 2.

Dr. Jyoti Gaur | Materials Science | Young Scientist Award

Dr. Jyoti Gaur | Materials Science | Young Scientist Award

Rayat Bahra University | Greater Mohali | India

Dr. Jyoti Gaur is a dynamic materials scientist and nanotechnology researcher recognized for her pioneering work in the synthesis, characterization, and environmental applications of nanostructured materials. She holds a Ph.D. in Materials Science from RIMT University, Punjab, India, and currently serves as an Assistant Professor of Research at Rayat Bahra University, Mohali. With 29 published documents, an h-index of 9, and 383 citations from 307 sources, Dr. Gaur has demonstrated consistent excellence in research and innovation. Her studies primarily focus on green synthesis of metal oxide nanoparticles, photocatalytic degradation of organic dyes, and the fabrication of eco-friendly nanocomposites for environmental remediation and antimicrobial applications. She has published in reputed journals such as Scientific Reports, Journal of Cleaner Production, RSC Advances, and Materials Today Sustainability, contributing significantly to sustainable nanomaterial development. Dr. Gaur’s innovative mindset has also led to four granted patents related to EMI shielding, photocatalytic devices, and composite material production technologies. Her interdisciplinary approach combines materials science, environmental chemistry, and nanotechnology to address pressing global challenges in pollution control and green energy. In recognition of her scientific excellence, she has received multiple awards, including the IOP Outstanding Reviewer Award (2023), IOP Trusted Reviewer Award (2024), and Best Oral Presentation Awards at both national and international conferences. She has also contributed to international collaborations, advancing applied nanoscience research through eco-sustainable approaches. Passionate about mentoring young researchers, Dr. Gaur actively promotes scientific inquiry and innovation in academic and industrial settings. Her continued pursuit of excellence in nanomaterials and sustainable technology positions her as a rising figure in materials research, making her contributions vital to advancing the frontiers of applied science and green innovation.

Profiles: Scopus | Orcid | Google Scholar

Featured Publications

Mahajan, M., Kumar, S., Gaur, J., Kaushal, S., Somvanshi, A., Kaur, H., Singh, G., et al. (2025). Role of cellulose, phenolic compounds, and water-soluble proteins in ZnO nanoparticle synthesis using Mangifera indica leaf extract for photocatalytic and antioxidant applications. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 137066.

Mahajan, M., Kaur, R., Gaur, J., Kumar, S., Kaushal, S., Kaur, H., Bajwa, A., et al. (2025). Surface-modified ZnO nanoparticles for enhanced environmental and biomedical performance. Hybrid Advances, 8, 100342.

Sood, S., Kumar, P., Raina, I., Misra, M., Kaushal, S., Gaur, J., Kumar, S., & Singh, G. (2025). Enhancing optoelectronic performance through rare-earth-doped ZnO: Insights and applications. Photonics, 12(5), 454.

Kumar, S., Kaur, A., Gaur, J., Singh, P., Kaur, H., Kaushal, S., Dalal, J., & Misra, M. (2025). State-of-the-art in Co₃O₄ nanoparticle synthesis and applications: Toward a sustainable future. ChemistrySelect, 10(6), e202405147.

Gaur, J., Kumar, S., Pal, M., Kaur, H., Rana, R. K., Bala, K., Singh, P. P., & Rajesh, C. (2025). Bio-functionalized, elongated hexagonal bi-pyramidal Citrus limetta/ZnO nanostructures as potential photocatalytic and seed germinating agents. Functional Composites and Structures, 5(3), 035003.