M.R.Rajan | Nanotechnology | Best Researcher Award

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Prof. Dr. M.R. Rajan | Nanotechnology | Best Researcher Award

Senior Professor | The Gandhigram Rural Institute- Deemed to be University | India

Dr. M. R. Rajan is a senior biologist whose four decades of academic service have significantly advanced environmental biotechnology, aquatic toxicology, nanomaterial-based interventions, and microbial ecology. As Senior Professor in the Department of Biology at the Gandhigram Rural Institute (Deemed to be University), Tamil Nadu, he has established a robust research portfolio addressing pollutant dynamics, eco-toxicological risks, sustainable aquaculture practices, and innovative bioremediation technologies. His early investigations on tannery effluents, sewage-supported fish culture, and organic–inorganic soil amendments contributed practical solutions for rural environmental management, while his recent work focuses on nanoparticle–organism interactions, green synthesis of metal and carbon-based nanomaterials, and the functional role of intestinal microbiota in enhancing fish growth and health. Dr. Rajan has authored numerous book chapters published by CRC Press, BP International, Agrobios, Science Publications, and other reputed outlets, highlighting themes such as wastewater purification, phytoremediation, antibacterial nanomaterials, and conservation biology. His extensive journal contributions many indexed in Scopus span topics including carbon quantum dots, silver and copper oxide nanoparticles, probiotic bacterial isolation, biomedical potential of graphene-based nanostructures, and sustainable valorisation of biological waste. His studies integrate biochemical, haematological, enzymatic, and ecotoxicological assessments, providing scientifically grounded insights for improving aquaculture safety, environmental restoration, and resource circularity. Through interdisciplinary collaborations and mentorship, he has strengthened research capacity in biological sciences and contributed to solutions addressing pollution, environmental health, and rural sustainability. His work continues to bridge laboratory innovation with societal needs, reinforcing his standing as a respected scholar and contributor to globally relevant biological research. His academic influence is reflected in 225 citations, 44 documents, and an h-index of 9, underscoring his meaningful contributions to contemporary biological science.

Profiles: Scopus | ORCID | LinkedIn

1. Muthuswami Ruby Rajan, & Chinnadurai Kaleeswaran. (2024). Evaluation of disparate multiplicities of copper oxide nanoparticles integrated feed on the growth and hematology of koi carp. Journal of Toxicological Studies.

2. Muthuswami Ruby Rajan, Rekha, M., & Dayana Senthamarai, M. (2024). Incorporation of Nano Selenium in fish diet and assessment of growth performance and biochemical criteria of Labeo rohita. Journal of Environmental Nanotechnology.

3. Muthuswami Ruby Rajan, & Dayana Senthamarai, M. (2023). Comparative study of green and chemical-synthesized selenium nanoparticles and its antibacterial assay against fish pathogens. Journal of Nanoscience and Technology.

4. Muthuswami Ruby Rajan, & Baluchamy Meenakumari. (2023). Impact of differential quantities of magnesium oxide nanoparticles on growth, haematological and biochemical characteristics of common carp Cyprinus carpio. International Journal of Creative Research Thoughts.

5. Rajan, M. R., & Brindha, G. (2022). Evaluation of dissimilar intestinal bacteria incorporated feeds on growth of ornamental fish Swordtail (Xiphophorus helleri). Letters in Applied Microbiology, 75(1).

Soo Jean Park | Chemical Biology | Best Researcher Award

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Dr. Soo Jean Park | Chemical Biology | Best Researcher Award

Senior Lecturer | Macquarie University | Australia

Dr Soo Jean Park is a leading researcher in organic chemistry and chemical ecology, specialising in arthropod semiochemistry, pheromone biology, and sustainable pest management. Her research advances the molecular and ecological understanding of pest–plant–natural enemy interactions, with particular focus on the chemical signals governing behaviour in economically significant insect species such as Queensland fruit fly, fall armyworm, and other Tephritidae pests. She integrates advanced analytical chemistry, organic synthesis, electrophysiology, and behavioural assays to uncover volatile profiles, identify bioactive natural products, and develop environmentally responsible pest control solutions. Her work has contributed significant insights into species-specific pheromone blends, age- and diet-dependent chemical emission patterns, rectal gland and cuticular chemistry, natural product attractants and repellents, and the chemical basis of reproductive isolation in sibling pest species. Dr Park has also driven innovation in softer insecticide design, natural product–based antifungal agents, and novel semiochemical applications aimed at reducing reliance on synthetic pesticides. Her research outputs, spanning 34 peer-reviewed publications in high-impact journals such as Scientific Reports, Molecules, Journal of Chemical Ecology, Journal of Pest Science, and PLoS ONE, reflect rigorous methodology, strong interdisciplinary collaboration, and substantial translational value for agriculture and biosecurity. She works closely with entomologists, ecologists, organic chemists, and industry partners to bridge fundamental chemical insights with applied pest management strategies, contributing to improved crop protection and ecological sustainability. Her findings support the development of precision monitoring tools, behaviour-modifying lures, and innovative integrated pest management frameworks with global relevance. Dr Park’s research influence is further evident through 347 citations, 34 documents, and an h-index of 10, demonstrating her growing impact in chemical ecology and sustainable insect management.

Profiles: Google Scholar | Scopus | ORCID

1. Park, S. J., Price, J. R., & Todd, M. H. (2012). Oxidative arylation of isochroman. The Journal of Organic Chemistry, 77(2), 949–955. Cited by: 118

2. Kempraj, V., Park, S. J., & Taylor, P. W. (2020). Forewarned is forearmed: Queensland fruit flies detect olfactory cues from predators and respond with predator-specific behaviour. Scientific Reports, 10(1), 7297. Cited by: 36

3. Pérez, J., Park, S. J., & Taylor, P. W. (2018). Domestication modifies the volatile emissions produced by male Queensland fruit flies during sexual advertisement. Scientific Reports, 8(1), 16503. Cited by: 34

4. Noushini, S., Perez, J., Park, S. J., Holgate, D., Mendez Alvarez, V., Jamie, I., … Jamie, J. (2020). Attraction and electrophysiological response to identified rectal gland volatiles in Bactrocera frauenfeldi (Schiner). Molecules, 25(6), 1275. Cited by: 27

5. Noushini, S., Perez, J., Park, S. J., Holgate, D., Jamie, I., Jamie, J., & Taylor, P. (2019). Rectal gland chemistry, volatile emissions, and antennal responses of male and female banana fruit fly, Bactrocera musae. Insects, 11(1), 32. Cited by: 25

Fritz Pragst | Medicinal Chemistry | Best Paper Award

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Prof. Dr. Fritz Pragst | Medicinal Chemistry | Best Paper Award

Guest Scientist | Humboldt University of Berlin | Germany

Prof. Dr. Fritz Pragst is a distinguished scholar in forensic and analytical toxicology whose work has significantly shaped modern toxicological science, evidence interpretation, and laboratory methodology. With an academic career spanning several decades, he has established himself as a leading authority in systematic toxicological analysis, forensic chemistry, and biomarker research, contributing to both foundational understanding and applied forensic practice. His scientific influence is demonstrated through 147 published documents, more than 6,170 citations, and an h-index of 43, reflecting consistent scholarly impact, high research relevance, and continued citation in contemporary toxicology literature. His pioneering contributions to hair analysis methodology, including alcohol biomarkers such as ethyl glucuronide and drug exposure evaluation in cases involving familial substance misuse, have provided globally referenced frameworks for long-term toxicological monitoring, legal case assessments, and public health applications. His work addresses complex analytical challenges, including differentiation between substance exposure routes, interpretation of low-level toxicological data, validation of forensic laboratory workflows, and development of ethical and scientifically defensible interpretation models. Beyond research, he has actively contributed to scientific societies, served in editorial and advisory roles, and engaged in extensive collaboration across multidisciplinary research networks, thereby supporting international knowledge exchange and capacity building within toxicology and forensic science communities. His scholarly output also demonstrates a commitment to solving real-world challenges, including improving diagnostic accuracy, enhancing substance abuse monitoring, and supporting fair use of toxicological evidence in legal and clinical environments. Through his influential publications, leadership roles, and contributions to methodological rigor and scientific education, Prof. Dr. Fritz Pragst has made a lasting impact on global forensic toxicology, ensuring that analytical science continues to advance with accuracy, ethical integrity, and societal relevance.

Profiles : Scopus | ResearchGate

Pragst, F. (2025). Systematic toxicological analysis in forensic and clinical laboratories: a challenging task of analytical chemistry. ChemTexts, 11(2).

Pragst, F., & Balíková, M. A. (2006). State of the art in hair analysis for detection of drug and alcohol abuse. Clinica Chimica Acta, 370(1–2), 17–49.

Pragst, F. (2022). Is there a relationship between abuse of alcohol and illicit drugs seen in hair results? Drug Testing and Analysis. (2025 listing for 2025 issues)

Prof. Dr. Fritz Pragst has significantly advanced forensic and clinical toxicology through pioneering work in systematic toxicological analysis and hair‐based drug detection methods, shaping global standards and improving public health, justice systems, and medico-legal investigations. His research continues to inspire innovation, strengthen scientific reliability, and support safer societies worldwide.

Chang Soon Huh | Physical Chemistry | South Korea

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Assist. Prof. Dr. Chang Soon Huh | Physical Chemistry | South Korea

Assistant Professor | Dong-Eui University | South Korea

Dr. Chang-soon Huh is an emerging researcher recognized for his growing contributions to analytical chemistry, biosensing technologies, and nanomaterial-assisted detection systems. With 13 peer-reviewed publications, 50 citations, and an h-index of 3, he demonstrates a steadily rising academic influence supported by methodologically robust and application-driven studies. His work integrates fluorescence spectroscopy, biomolecular recognition, and engineered nanomaterials to create rapid, sensitive, and cost-efficient diagnostic platforms capable of addressing contemporary analytical challenges. One of his notable achievements includes the development of a fluorescent detection strategy for alkaline phosphatase based on gold nanoclusters and p-nitrophenyl phosphate, underscoring his ability to connect fundamental chemical principles with practical biosensing innovation. His research portfolio highlights strong interdisciplinary collaboration, engaging co-authors across materials science, biotechnology, and chemical engineering, which enriches the scientific depth and applicability of his studies. These collaborations support novel advancements in high-sensitivity detection systems, enabling precise monitoring of biochemical reactions and contributing to improved diagnostic and environmental assessment methodologies. Beyond quantitative publication metrics, his work demonstrates broader societal relevance, particularly in areas requiring early disease detection, quality assurance in bioprocessing, and real-time analysis of biochemical pathways. His commitment to scientific rigor, innovation, and problem-solving positions him as a promising researcher with expanding influence in the global analytical science community. Through consistent scholarly output and an expanding citation record, Dr. Huh continues to advance impactful research that aligns with emerging needs in biosensing, nanotechnology, and chemical diagnostics.

Profiles : Scopus | ResearchGate

Featured Publications

Kim, S.-H., Huh, C.-S., & Kim, M.-M. (2025). Rapid and sensitive detection of alkaline phosphatase based on fluorescent gold nanoclusters and p-nitrophenyl phosphate. Journal of Bioscience and Bioengineering. Citations: 1

Lee, S. E., & Huh, C.-S. (2025). Application of smartphones to measurements of reducing power related to antioxidant activity. Journal of Analytical Chemistry.

Kim, G. H., Huh, C.-S., & Kim, M.-M. (2024). Development of a smartphone-based method for measuring the antioxidant efficacy of commercial beverages. Current Analytical Chemistry.

Talapphet, N., & Huh, C.-S. (2024). A smartphone colorimetric development with TMB/H₂O₂/HRP reaction system for hydrogen peroxide detection and its applications. Journal of Analytical Chemistry. Citations: 10

Talapphet, N., & Huh, C.-S. (2024). Development of gold nanocluster complex for the detection of tumor necrosis factor-alpha based on immunoassay. Journal of Immunological Methods. Citations: 4

Chang-soon Huh’s work advances analytical science through innovative biosensing and nanomaterial-based detection systems that improve accuracy, speed, and accessibility in chemical and biochemical analysis. His research supports global innovation in health diagnostics and contributes to practical technologies that strengthen scientific, industrial, and societal advancements.

Arul Pundi | Materials Chemistry | Chemical Scientist Award

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Dr. Arul Pundi | Materials Chemistry | Chemical Scientist Award

Postdoctoral Research Fellow | Feng Chia University | Taiwan

Dr. Pundi Arul is an emerging early-career researcher at Feng Chia University, Taichung, Taiwan, contributing to advancing photocatalysis, polymer composites, and defect-engineered semiconductor materials. He has authored 14 peer-reviewed publications that have collectively received 328 citations, demonstrating the growing visibility and scientific influence of his work within the global materials science community, and his h-index of 10 underscores the impact of his research relative to his career stage. His primary research focus lies in the design, synthesis, and optimization of vacancy-engineered polymeric and graphitized carbon nitride photocatalysts, materials that hold significant promise for solar energy conversion, environmental remediation, and sustainable oxidation–reduction reactions. His recent comprehensive review on vacancy defects provides valuable mechanistic insights and offers strategic guidance for future photocatalyst development. Beyond defect engineering, Dr. Arul’s research interests encompass polymer science, nanomaterials, photocatalytic reaction pathways, and semiconductor modifications aimed at improving light absorption and charge-carrier dynamics. He frequently employs advanced characterization tools to probe structure–property relationships, contributing to more rational and efficient catalyst design. Collaboration is a key dimension of his scientific work, reflected in his co-authorship with 25 researchers across interdisciplinary and international projects, strengthening the depth and application potential of his studies in sustainable materials and green energy technologies. With research aligned toward global priorities in clean energy and environmental protection, Dr. Arul’s contributions support the development of next-generation photocatalytic systems capable of pollution mitigation and renewable energy harvesting. Through his expanding research trajectory, he continues to establish himself as a promising scientist in materials chemistry and photocatalytic science.

Profiles : Google Scholar | Scopus | ORCID

Featured Publications

Pundi, A., Chang, C. J., Chen, J., Hsieh, S. R., & Lee, M. C. (2021).A chiral carbazole based sensor for sequential “on-off-on” fluorescence detection of Fe³⁺ and tryptophan/histidine.
Sensors and Actuators B: Chemical, 328, 129084.Cited by: 95

Pundi, A., & Chang, C. J. (2022).Recent advances in synthesis, modification, characterization, and applications of carbon dots.Polymers, 14(11), 2153.Cited by: 67

Pundi, A., Chang, C. J., Chen, Y. S., Chen, J. K., Yeh, J. M., Zhuang, C. S., & Lee, M. C. (2021).An aniline trimer-based multifunctional sensor for colorimetric Fe³⁺, Cu²⁺ and Ag⁺ detection, and its complex for fluorescent sensing of L-tryptophan.Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 247, 119075.Cited by: 34

Reddy, P. M., Hsieh, S. R., Lee, M. C., Chang, C. J., Pundi, A., Chen, Y. S., Lu, C. H., & others. (2019).Aniline trimer based chemical sensor for dual responsive detection of hazardous CN¯ ions and pH changes.Dyes and Pigments, 164, 327–334. Cited by: 27

Pundi, A., & Chang, C. J. (2023).Recent developments in the preparation, characterization, and applications of chemosensors for environmental pollutants detection.Journal of Environmental Chemical Engineering, 11(5), 110346.Cited by: 25

Dr. Pundi Arul’s research advances next-generation sensing and photocatalytic materials, enabling cleaner environments, sustainable technologies, and high-precision analytical tools. His innovations contribute directly to global efforts in environmental protection, renewable energy, and advanced material design.

Devesh Barshilia | Nanotechnology | Best Researcher Award

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Dr. Devesh Barshilia | Nanotechnology | Best Researcher Award

Assistant Researcher | National Chung Cheng University | Taiwan

Dr. Devesh Barshilia is an emerging multidisciplinary scientist whose research spans biosensors, nanophotonics, optofluidic platforms, semiconductor optoelectronics, and integrated photonic sensing systems, positioned at the intersection of materials science, photonics, and biomedical engineering to develop high-performance, low-cost, and ultra-sensitive detection technologies for healthcare, environmental monitoring, and analytical diagnostics. A major focus of his work is the design and optimization of planar waveguide–based optofluidic sensors for rapid, real-time, and label-free refractive index detection, with his highly cited publication on waveguide sensors highlighting his strong impact in optical detection research. He has also made notable advances in particle plasmon resonance integrated biosensing by synergizing plasmonic field enhancement with guided-wave optics to achieve superior biochemical sensitivity, while his contributions to guided-mode resonance (GMR) biosensing demonstrate his ability to engineer compact, precise, and clinically relevant optical devices. His work on nanogold-linked immunosorbent assays is especially impactful, enabling improved early detection of sepsis-associated biomarkers such as procalcitonin for point-of-care diagnostics. Parallel to his biosensing developments, Dr. Barshilia has produced influential research in semiconductor photonic devices including GeSn-based short-wave infrared phototransistors, graphene-based flexible photodetectors, and engineered silicon-dioxide nanostructures, with publications in leading journals such as Optics Express, Optics Letters, Advanced Optical Materials, and Nano Letters. By integrating waveguide-enhanced spectroscopy, nanoplasmonics, and advanced biosensing microarchitectures, he is advancing miniaturized diagnostic tools for DNA, protein, and biomarker detection. With 183 citations, an h-index of 6, and a steadily expanding publication record, Dr. Barshilia is establishing himself as a rising contributor to next-generation biosensing and integrated photonic diagnostics.

Profiles: ORCID | Google Scholar | LinkedIn | ResearchGate

Featured Publications

Barshilia, D., Huang, J.-J., Komaram, A. C., Chen, Y.-C., Chen, C.-D., Syu, M.-Y., Chao, W.-C., Chau, L.-K., & Chang, G.-E. (2024). Ultrasensitive and rapid detection of procalcitonin using waveguide nanogold-linked immunosorbent assay for early sepsis diagnosis.

Barshilia, D., Komaram, A. C., Chen, P.-C., Chau, L.-K., & Chang, G.-E. (2022). Slab waveguide-based particle plasmon resonance optofluidic biosensor for rapid and label-free detection. Analyst, 147(20), 4417–4425.

Barshilia, D., Chau, L.-K., & Chang, G.-E. (2020). Low-cost planar waveguide-based optofluidic sensor for real-time refractive index sensing. Optics Express, 28(19), 27337–27345.

Barshilia, D., Komaram, A. C., Chau, L.-K., & Chang, G.-E. (2024). Waveguide-enhanced nanoplasmonic biosensor for ultrasensitive and rapid DNA detection. Micromachines, 15(9), 1169.

Yeh, C.-T., Barshilia, D., Hsieh, C.-J., Li, H.-Y., Hsieh, W.-H., & Chang, G.-E. (2021). Rapid and highly sensitive detection of C-reactive protein using a robust self-compensated guided-mode resonance biosensing system for point-of-care applications. Biosensors, 11(12), 523.

Dr. Devesh Barshilia’s innovative work in biosensors, optofluidics, and nanophotonic detection systems is advancing the future of rapid, ultra-sensitive medical diagnostics and smart analytical technologies. His breakthroughs in waveguide-enhanced and plasmonic sensing platforms contribute directly to early disease detection, next-generation point-of-care solutions, and high-impact industrial applications. Through pioneering research that bridges photonics, biotechnology, and semiconductor engineering, he is shaping globally relevant innovations that strengthen healthcare, scientific progress, and technological advancement.

 

Tamer Saleh | Green Chemistry | Chemical Scientist Award

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Prof. Dr. Tamer Saleh | Green Chemistry | Chemical Scientist Award

Professor | University of Jeddah | Saudi Arabia

Dr. Tamer S. Saleh is a distinguished researcher recognized for substantial contributions to sustainable chemistry, advanced catalysis, green synthesis, nanomaterials, and biotechnology, with a strong publication record exceeding 96 peer-reviewed articles, 1,928 citations, and an h-index of 27. His research integrates innovative catalytic methodologies with environmentally responsible chemical processes, demonstrating expertise in developing supramolecular coordination polymers, metal-decorated biopolymers, layered double hydroxide systems, and novel organocatalysts that enable greener approaches for heterocycle construction, CH-functionalization, and cycloaddition reactions. He has advanced modern synthetic chemistry through sonophotocatalysis, pressure-assisted reactors, and hybrid catalytic platforms that improve efficiency, selectivity, and sustainability across diverse transformations. In analytical and materials chemistry, he has contributed significantly to the design of carbon dot–gold nanoparticle composites, fluorescence-based sensing probes, and SERS-enabled biosensors with enhanced sensitivity for detecting neurotransmitters and microbial metabolites, enabling progress in diagnostics, environmental monitoring, and chemical safety. His interdisciplinary work further includes biotechnological innovations such as optimized bioreactor fermentation, valorization of agricultural waste, and microbial lipid production using oleaginous yeasts, highlighting impactful pathways toward sustainable resource utilization and microbial engineering. Research on oxidative stress regulation in pathogenic fungi, metabolite profiling, and the development of novel bioactive compounds adds to his broad scientific portfolio with relevance to public health and drug discovery. With more than 160 collaborative co-authors worldwide, his scholarship is marked by strong scientific partnerships and global visibility. Through his commitment to methodological rigor, innovation, and sustainability-driven solutions, Dr. Saleh continues to contribute meaningfully to advancements in green chemistry, catalysis, materials science, and biotechnology, reinforcing the societal relevance of modern chemical research.

Profiles : Scopus | ORCID | ResearchGate

Featured Publications

Saleh, T. S., Al-Bogami, A. S., Aqlan, F. M., & Akhdhar, A. (2026). Exploring the molecular structure of green-synthesized aza-Michael addition products: 2D NMR confirms novel pyrazoles. Journal of Molecular Structure.

El-Said, W. A., Akhdhar, A., Al-Bogami, A. S., & Saleh, T. S. (2025). Design and green synthesis of carbon dots/gold nanoparticle composites and their applications for neurotransmitter sensing based on emission spectroscopy. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy.

Saleh, T. S., & Al-Bogami, A. S. (2025, November 4). Straightforward synthesis of thiophene bioisosteres of the pyrrolo[3,2-c]quinoline framework from Martinelline alkaloids. Molbank. El-bendary, M. M., Akhdhar, A., Davaasuren, B., Al-Bogami, A. S., & Saleh, T. S. (2025, October 10). Unveiling silver catalysis to access 5-substituted tetrazole through [3+2] cycloaddition reaction, utilizing a novel silver supramolecular coordination polymer–based catalyst: A new green horizon. Catalysts.

Al-Romaizan, A. N., Altuna, I. A., Larruskain, M. G., Alghamdi, K. S., Alzhrani, G., Saleh, T. S., … & Hillenbrand, R. (2025, September). Copper-decorated chitosan organocatalyst for sonophotocatalytic C–H arylation of pyrazoles: Mechanistic insights and eco-friendly perspective. Carbohydrate Polymer Technologies and Applications.

Dr. Tamer S. Saleh’s research advances sustainable chemical innovation by developing green catalytic systems, eco-friendly synthesis pathways, and high-performance sensing materials that address critical scientific and industrial challenges. His work supports cleaner technologies, enhances analytical capabilities, and contributes to global efforts toward environmentally responsible chemical manufacturing.

Mainak Saha | Materials Chemistry | Best Researcher Award

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Dr. Mainak Saha | Materials Chemistry | Best Researcher Award

Postdoctoral Researcher | National Institute for Materials Science | Japan

Dr. Mainak Saha is an emerging materials science researcher whose work demonstrates notable advancements in additive manufacturing, alloy development, and microstructural engineering, with a strong focus on designing high-performance metal matrix composites and understanding the intricate relationships between processing conditions, segregation behavior, and resulting mechanical properties. With a portfolio comprising 14 peer-reviewed publications and 86 citations, supported by an h-index of 5 , his contributions reflect a growing influence within the global materials research community. His studies frequently explore the development of lightweight, high-strength alloy systems, the thermodynamic and kinetic factors governing phase formation, and strategies for microstructural refinement that enhance strength, durability, and thermal stability in engineered metals. Notably, his research on segregation-induced microstructural refinement in FeMnAlC-TiB metal matrix composites produced via laser powder bed fusion  highlights his expertise in advanced manufacturing pathways and his ability to integrate metallurgical principles with cutting-edge fabrication technologies. Dr. Saha has collaborated with over 80 co-authors, illustrating his active participation in multidisciplinary research teams and underscoring his capacity to contribute significantly to collaborative scientific initiatives . His work intersects with critical industrial fields such as transportation, energy, and high-performance manufacturing, where the need for innovative, lightweight, corrosion-resistant, and structurally reliable materials is rapidly increasing. Through his research, he contributes to solving practical engineering challenges, improving manufacturing efficiency, and supporting global efforts toward sustainable, high-performance material solutions. His scientific output reflects both academic rigor and technological relevance, bridging fundamental metallurgical science with applied engineering innovation. As he continues to expand his research portfolio, Dr. Saha’s contributions are expected to further influence materials design methodologies, support the development of next-generation structural materials, and strengthen the broader scientific understanding of microstructure-property relationships in advanced alloys .

Profiles : Google Scholar | Scopus | ORCID 

Featured Publications

Saha, M., & Mallik, M. (2021). Additive manufacturing of ceramics and cermets: Present status and future perspectives. Sādhanā, 46(3), 162.
Cited by: 40

Gault, B., Saksena, A., Sauvage, X., Bagot, P., Aota, L. S., Arlt, J., Belkacemi, L. T., … Saha, M. (2024). Towards establishing best practice in the analysis of hydrogen and deuterium by atom probe tomography. Microscopy and Microanalysis, 30(6), 1205–1220.*
Cited by: 30

Gururaj, K., Saha, M., Maurya, S. K., Nama, R., Alankar, A., Ponnuchamy, M. B., … (2022). On the correlative microscopy analyses of nano-twinned domains in 2 mol% zirconia-alloyed yttrium tantalate thermal barrier material. Scripta Materialia, 212, 114584.
Cited by: 17

Saha, M., Ponnuchamy, M. B., Sadhasivam, M., Mahata, C., Vijayaragavan, G., … (2022). Revealing the localization of NiAl-type nano-scale B2 precipitates within the BCC phase of Ni-alloyed low-density FeMnAlC steel. JOM, 74(8), 3181–3190.
Cited by: 15

 Mallik, M., & Saha, M. (2021). Carbon-based nanocomposites: Processing, electronic properties and applications. In Carbon nanomaterial electronics: Devices and applications (pp. 97–122).
Cited by: 15

Dr. Mainak Saha’s research advances the development of high-performance alloys and additive manufacturing technologies, driving innovations that strengthen modern engineering, enhance industrial efficiency, and support global progress in sustainable, next-generation materials. His work continues to bridge fundamental science with real-world technological impact.

Liliya Faizullina | Organic Chemistry |Best Researcher Award

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Assoc. Prof. Dr. Liliya Faizullina | Organic Chemistry | Best Researcher Award

 Researcher | Ufa Institute of Chemistry | Russia

Faizullina L. Kh is a distinguished researcher in synthetic organic chemistry, recognized for her sustained contributions to the development of chiral building blocks, advanced reaction methodologies, and structurally intricate organic frameworks. With a scholarly record comprising 48 publications, 180 citations, and an h-index of 6, she has established a solid research footprint in asymmetric synthesis and the strategic transformation of bio-derived molecular precursors. Her work extensively explores the reactivity and synthetic versatility of levoglucosenone-based intermediates, including Michael adducts, Diels Alder products, and spirocyclic derivatives, which serve as crucial synthons for the construction of stereochemically rich and biologically relevant molecules. Notable recent studies include the preparation of chiral spirocyclobutanones, investigations into Cyrene as a chiral synthon, synthetic approaches toward acetogenin-type structures, and the design of key intermediates used in the assembly of loganin-related frameworks. These contributions reflect her strong command over stereochemical control, mechanistic interpretation, and multi-step synthetic planning, positioning her as an influential figure in the field. Beyond structural synthesis, her research frequently incorporates the evaluation of the biological activity of synthesized compounds, highlighting a multidisciplinary perspective that bridges organic chemistry with potential pharmacological applications. With collaborations involving more than 40 co-authors, her work demonstrates a commitment to interdisciplinary advancement and collective scientific inquiry. Her research also emphasizes sustainability through the adoption of bio-based starting materials and greener synthetic approaches, contributing to environmentally responsible chemical development. By enhancing access to complex chiral molecules and enabling new directions in medicinally relevant scaffold design, her work carries both scientific and societal significance. Faizullina L. Kh continues to expand the frontiers of modern synthetic organic chemistry through rigorous scholarship, collaborative engagement, and a sustained dedication to innovation in molecular synthesis.

Khalilova, Y. A., & Faizullina, L. Kh. (2025). Recent applications of Cyrene as a chiral synthon. Organic & Biomolecular Chemistry.

Akhmetdinova, N., Biktagirov, I., & Faizullina, L. Kh. (2025, November 6). Transformation of the cyclohexane ring to the cyclopentane fragment of biologically active compounds. Beilstein Journal of Organic Chemistry.

Galimova, Y. S., Salikhov, Sh. M., & Faizullina, L. Kh. (2025, September). Michael adduct of levoglucosenone and α-carboethoxycyclododecanone in the synthesis of a chiral spirocyclobutanone. Russian Journal of General Chemistry.

Galimova, Y. S., Kupova, O. Yu., Salikhov, Sh. M., & Faizullina, L. Kh. (2025, April). Approaches to the synthesis of acetogenins based on the Michael adducts of levoglucosenone and α-carboethoxycyclododecanone and analysis of their biological activity. Russian Journal of General Chemistry.

Khalilova, Y. A., Karamisheva, L. Sh., Salikhov, Sh. M., Galimova, Y. S., & Faizullina, L. Kh. (2024, August 13). Synthesis of N-alkyl-substituted aziridines and oxazolidine based on levoglucosenone derivatives.

 

Chung-Yin | Supramolecular Chemistry | Best Researcher Award

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Dr. Chung-Yin Lin | Supramolecular Chemistry | Best Researcher Award

Associated Principle Investigator | Chang Gung University | Taiwan

Dr. Chungyin Lin is a distinguished researcher whose work spans neuroscience, molecular biochemistry, and advanced diagnostic technologies, with a strong record of scientific influence demonstrated by 43 peer-reviewed publications and more than 1,817  citations. His research portfolio encompasses the molecular mechanisms underlying neurodegenerative disorders, with notable investigations into tau-related neuroinflammation, mitochondrial dysfunction, dysregulation of choline metabolism, and the therapeutic potential of bioactive compounds such as citicoline and kynurenic acid. Dr. Lin has also contributed significantly to translational diagnostic science through the development of paper-based molecularly imprinted sensing platforms designed for sensitive and accessible biomarker detection, reflecting a broader commitment to bridging biological insights with practical clinical tools. His publications in widely recognized journals highlight a sustained focus on disorders such as Huntington’s disease and Parkinson’s disease, where his findings support ongoing advancements in early diagnosis, therapeutic targeting, and neuroprotective intervention strategies. Dr. Lin’s work is further strengthened by extensive interdisciplinary collaboration, having co-authored studies with over 130 researchers from diverse scientific domains, including clinicians, pharmacologists, materials scientists, and biomedical engineers. These collaborations have accelerated progress in understanding disease-related biochemical pathways, developing innovative detection methods, and proposing new therapeutic hypotheses, thereby enhancing the societal and scientific impact of his research. With an h-index of 21, Dr. Lin continues to contribute meaningfully to global biomedical research through rigorous experimentation, integrative methodology, and a vision oriented toward improving human health through scientific innovation.

Featured Publications

Lin, T.-H., Tseng, P.-H., Chen, I.-C., & Chen, C.-M. (2025). The potential of mulberry (Morus alba L.) leaf extract against pro-aggregant Tau-mediated inflammation and mitochondrial dysfunction.

Lin, T.-C., Lin, C. Y., Hwang, Y.-T., & Tai, D.-F. (2025). Paper-based molecularly imprinted film designs for sensing human serum albumin.

Chang, K.-H., Cheng, M.-L., Tang, H.-Y., et al., & Chen, C.-M. (2024). Dysregulation of choline metabolism and therapeutic potential of citicoline in Huntington’s disease.

Chen, C.-M., Huang, C.-Y., Lai, C.-H., et al., & Lin, C. Y. (2024). Neuroprotection effects of kynurenic acid-loaded micelles for the Parkinson’s disease models.

Yang, P.-N., Chen, W.-L., Lee, J.-W., et al., & Lee-Chen, G.-J. (2023). Coumarin-chalcone hybrid LM-021 and indole derivative NC009-1 targeting inflammation and oxidative stress to protect BE(2)-M17 cells against α-synuclein toxicity.

Dr. Chungyin Lin’s research advances global understanding of neurodegeneration while driving innovative diagnostic and therapeutic strategies that address critical unmet needs in neurological health. His interdisciplinary work bridges molecular science, technology, and clinical application, contributing meaningful solutions that enhance healthcare outcomes and societal well-being.