Prof. Raoelina Andriambololona | Physics | Best Researcher Award

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Prof. Raoelina Andriambololona | Physics | Best Researcher Award

Emeritus Professor at Institut National des Sciences et Techniques Nucléaires, Madagascar

Prof. Raoelina Andriambololona 🇲🇬 is an iconic figure in the global scientific community, renowned for his pioneering contributions to nuclear physics, theoretical science, and sustainable development. With over six decades of dedicated service, he has transformed science and technology education in Madagascar and across Africa. From being a CNRS researcher in France to establishing world-class research institutions back home, Prof. Raoelina’s vision is deeply rooted in innovation, self-reliance, and scientific ethics. A prolific author of 250+ publications 📚 and several university-level books, he continues to inspire generations of physicists. His leadership in nanotechnology, environmental protection, and science diplomacy has earned him numerous global honors 🏅. Fluent in Malagasy, French, and English, and with professional footprints in over 30 countries, Prof. Raoelina stands as a beacon of excellence, dedication, and intellectual humility. His legacy is not only academic but deeply humanistic 🌱💡.

Professional Profile 

🎓 Education

Prof. Raoelina’s academic odyssey began in Madagascar and blossomed at the University of Aix-Marseille, France 🇫🇷, where he obtained his Doctorat ès Sciences d’État in 1967. His earlier credentials include a Doctorate of 3rd Cycle in Theoretical Physics (1962), diplomas in pure and applied mathematics (1957–1958), and a degree in physical sciences. This rich foundation empowered his intellectual pursuit across quantum theory, linear algebra, and advanced mechanics 🧠📘. His education wasn’t just confined to acquiring degrees but focused on laying the groundwork for a national educational revolution in Madagascar. The blend of French scientific rigor and Malagasy passion shaped him into a transcontinental academic luminary. His multilingual fluency in Malagasy, French, and English further cemented his ability to bridge knowledge between diverse cultures 🌐🗣️. His journey embodies a harmonious union of deep theoretical insight and practical academic engineering.

🧪 Professional Experience

Prof. Raoelina’s professional career radiates across continents and sectors, beginning as a researcher at CNRS–Marseille in the 1960s and later as Professor Titulaire in Madagascar by 1972 🧑‍🏫. He was instrumental in founding multiple institutions from scratch, including the Laboratoire de Physique Nucléaire and the Institut National des Sciences et Techniques Nucléaires (INSTN). Nationally, he shaped physics education, built observatories, and opened the first graduate programs in nuclear physics. Internationally, he served as an advisor to the UNDP, IAEA liaison officer for decades, Fulbright professor in the U.S., and UNESCO expert advisor 🌍🔬. His role as Scientific Advisor to the President of Madagascar (1986–1991) further reflects his unique ability to integrate science with policy and national development. Raoelina is not only a pioneer in academia but a strategist in science infrastructure development, capacity building, and global knowledge networks 🧭🏗️.

🔬 Research Interests

Prof. Raoelina’s research traverses a remarkable spectrum—ranging from particle physics, quantum mechanics, and nuclear spectroscopy to nanotechnology, fractional calculus, and environmental science. His scientific curiosity has been deeply interdisciplinary, focusing also on linear and multilinear algebra, development studies, and ethics in science 🧠🌿. His commitment to applied research is evident in his work on X-ray fluorescence for ore analysis, radiation protection, and environmental monitoring. With a sharp lens on the challenges of developing countries, he emphasizes indigenous knowledge, sustainability, and technology transfer 📈. His vision of endogenous development and the use of native language in science education marks him as both a thought leader and cultural reformist. His 250+ publications are not just academic outputs but serve as knowledge vehicles across generations and geographies. Prof. Raoelina’s research transcends the lab—blending intellect with societal impact 🎯📖.

🏆 Awards and Honors

Prof. Raoelina’s excellence has been globally acknowledged through numerous prestigious honors 🌟. He is the 2020 recipient of the TWAS-C.N.R. Rao Award for Scientific Research and holds national decorations such as the Grand-Croix de 2ème classe de l’Ordre National Malagasy (1997) and Commandeur de l’Ordre du Mérite de Madagascar (1991). These awards recognize not only his scholarly brilliance but also his unwavering dedication to national science development. His election to the African Academy of Sciences, TWAS, and the New York Academy of Sciences confirms his impact on the international stage 🌐. As the founding president of several national scientific societies and advisory boards, his role as a scientific statesman is undeniable. Through music, ethics, and education, his contributions have extended beyond the lab and lecture hall. These accolades are testaments to a life passionately lived in service of knowledge and humanity 🕊️📜.

📚 Publications Top Note 

1.Title: Assessment of soil redistribution rates by 137Cs and 210Pbex in a typical Malagasy agricultural field
Authors: N Rabesiranana, M Rasolonirina, AF Solonjara, HN Ravoson, …
Year: 2016
Citations: 32
Source: Journal of Environmental Radioactivity, Volume 152, Pages 112-118
Summary:
This study investigates soil erosion and redistribution rates in agricultural fields of Madagascar using radioactive tracers 137Cs and 210Pbex. These isotopes serve as markers to quantify soil movement and deposition, offering insights into land degradation processes in typical Malagasy agricultural settings.

2.Title: Algèbre linéaire et multilinéaire
Author: R Andriambololona
Year: 1986
Citations: 28
Source: Applications, Collection LIRA, INSTN Madagascar
Summary:
A comprehensive treatise on linear and multilinear algebra, focusing on theoretical foundations and applications. It is a foundational text for mathematical education and research in Madagascar, especially in algebraic structures relevant to physics and engineering.

3.Title: Top soil radioactivity assessment in a high natural radiation background area: The case of Vinaninkarena, Antsirabe—Madagascar
Authors: N Rabesiranana, M Rasolonirina, F Terina, AF Solonjara, …
Year: 2008
Citations: 24
Source: Applied Radiation and Isotopes, Volume 66, Issue 11, Pages 1619-1622
Summary:
This paper assesses the natural radioactivity levels in the topsoil of Vinaninkarena, an area with high natural radiation background in Madagascar. The findings provide important baseline data for environmental radiation monitoring and public health considerations.

4.Title: Dispersion Operators Algebra and Linear Canonical Transformations
Authors: R Andriambololona, RT Ranaivoson, R Hasimbola Damo Emile, …
Year: 2017
Citations: 22
Source: International Journal of Theoretical Physics, Volume 56, Issue 4, Pages 1258-1273
Summary:
This article presents a theoretical framework linking dispersion operators algebra with linear canonical transformations, important in mathematical physics and quantum mechanics. It advances the understanding of operator theory in quantum contexts.

5.Title: Study on a phase space representation of quantum theory
Authors: T Ranaivoson, R Andriambololona, R Hanitriarivo, R Raboanary
Year: 2013
Citations: 21
Source: arXiv preprint arXiv:1304.1034
Summary:
The paper explores phase space formulations of quantum mechanics, offering novel insights into representing quantum states and operators. It emphasizes the theoretical and computational advantages of this approach.

6.Title: Cleft lip and palate in Madagascar 1998–2007
Authors: RA Rakotoarison, AE Rakotoarivony, N Rabesandratana, …
Year: 2012
Citations: 20
Source: British Journal of Oral and Maxillofacial Surgery, Volume 50, Issue 5, Pages 430-434
Summary:
An epidemiological study documenting the incidence, treatment, and outcomes of cleft lip and palate cases in Madagascar over a decade. The research highlights healthcare challenges and the need for improved surgical interventions.

7.Title: Definitions of real order integrals and derivatives using operator approach
Author: R Andriambololona
Year: 2012
Citations: 20
Source: arXiv preprint arXiv:1207.0409
Summary:
This paper introduces an operator-based method to define fractional calculus concepts such as real order integrals and derivatives, contributing to the mathematical theory with potential applications in physics and engineering.

8.Title: Linear canonical transformations in relativistic quantum physics
Authors: RT Ranaivoson, R Andriambololona, H Rakotoson, R Raboanary
Year: 2021
Citations: 17
Source: Physica Scripta, Volume 96, Issue 6, 065204
Summary:
The authors analyze the role of linear canonical transformations in the framework of relativistic quantum physics, exploring their implications for the symmetry and dynamics of quantum systems.

9.Title: A study of the Dirac-Sidharth equation
Authors: R Andriambololona, C Rakotonirina
Year: 2009
Citations: 16
Source: arXiv preprint arXiv:0910.2868
Summary:
The paper investigates the Dirac-Sidharth equation, a modification of the Dirac equation in quantum mechanics, focusing on its mathematical properties and physical interpretations.

10.Title: Time-Frequency analysis and harmonic Gaussian functions
Authors: T Ranaivoson, R Andriambololona, R Hanitriarivo
Year: 2013
Citations: 15
Source: arXiv preprint arXiv:1303.1909
Summary:
This research develops methods for time-frequency analysis using harmonic Gaussian functions, relevant for signal processing and quantum mechanics.

11.Title: Mécanique quantique
Author: R Andriambololona
Year: 1990
Citations: 15
Source: Collection LIRA, INSTN Madagascar, pp. 25.387-394
Summary:
A foundational book on quantum mechanics, covering theoretical concepts, mathematical formalism, and applications. It serves as a key reference for students and researchers in Madagascar.

🧭 Conclusion

Prof. Raoelina Andriambololona is not merely a scientist—he is a visionary builder of nations through science 🌍🏛️. His unparalleled contributions in education, research, and policy over six decades mark him as a towering intellectual of Africa and the global South. With a career rooted in humility, foresight, and innovation, he has redefined what it means to be a scientist in service of humanity. His legacy is cemented in institutions, publications, and minds that continue to carry forward his mission 💡📚. Whether in physics, ethics, development, or music, Prof. Raoelina remains a multifaceted scholar and cultural pillar. His work exemplifies the role of science in shaping just, informed, and sustainable societies. As future generations draw inspiration from his life’s work, his name shall endure in the annals of both scientific discovery and national empowerment 🌟🧬.

Mr. Yogesh Bhardwaj | Cosmology | Best Researcher Award

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Mr. Yogesh Bhardwaj | Cosmology | Best Researcher Award

Research Scholar at Delhi Technological University, India

Yogesh Bhardwaj 🌌 is a visionary research cosmologist whose intellectual curiosity bridges the vast realms of the universe and the elegance of mathematics. A passionate seeker of cosmic truths, he combines the might of theoretical modeling with artificial intelligence 🤖 to explore the structure and evolution of the cosmos. With several peer-reviewed publications 📚 under his belt, Yogesh has not only contributed to academia but has inspired a new narrative of cosmological understanding. His interests span across modified gravity, general relativity, machine learning, and high-dimensional data analysis 📊. Off the academic track, he’s an avid cricket fan 🏏, music lover 🎶, and a speed napper 😴, embodying a balanced blend of intellect and spirit. His work ethic, rooted in discipline and constant self-improvement, reflects his admiration for thought leaders like Carl Sagan and Abdul Kalam. Yogesh is not just a scholar — he’s a cosmic thinker in action 🚀.

Professional Profile 

🎓 Education

Yogesh Bhardwaj’s educational journey 🚶‍♂️ is deeply embedded in the sciences of abstraction and exploration. Currently pursuing a Ph.D. in Applied Mathematics (2022–Present) from Delhi Technological University (DTU) 🧠, he is sculpting mathematical theories into models of universal phenomena. His doctoral work delves into cosmological modeling and theoretical physics, focusing on matter creation and gravitational interactions. Prior to this, he earned his Master of Science in Applied Mathematics (2019–2021) from the same esteemed institution, where he specialized in differential equations, numerical methods, and operations research. Beyond formal degrees, Yogesh is an avid self-learner 📖, having completed global MOOCs like “Data-Driven Astronomy” 🛰️ and Python bootcamps 💻 on platforms like Coursera and Udemy. These ventures expanded his computational and coding repertoire, aligning his mathematical insight with real-world astrophysical datasets. His education is not just credential-driven but passion-fueled, guided by a curiosity for the universe’s deepest mysteries 🌠.

💼 Professional Experience

Yogesh Bhardwaj has forged a dynamic career pathway where academia meets computation. Since January 2022, he has been a Research Fellow at Delhi Technological University, diving into high-impact research at the intersection of applied mathematics and cosmology 📈. His role includes developing theoretical models of the universe, managing research databases, and employing tools like Python 🐍 and Mathematica to analyze astronomical phenomena. Earlier, Yogesh contributed remotely to Course Hero (California, USA) and Chegg India as a Subject Matter Expert (2020–2021), where he mentored learners and provided advanced solutions in mathematics. His analytical precision, clarity of explanation, and conceptual depth helped shape the learning experience of countless students worldwide 🌎. His hands-on use of SPSS, R, MATLAB, and SQL showcases his adaptability in data science environments. Yogesh exemplifies the spirit of a 21st-century cosmologist—interdisciplinary, tech-savvy, and purpose-driven 🔧📘.

🔬 Research Interest

Yogesh Bhardwaj’s research universe revolves around the grandeur of cosmology, the elegance of general relativity, and the predictive power of machine learning 🌌📊. He specializes in exploring the large-scale structure of the cosmos, focusing on modified gravity theories, dark energy, and matter creation cosmology. Yogesh is particularly drawn to the mysteries of the universe’s expansion, the modeling of exotic fluids like the generalized Chaplygin gas, and the simulation of gravitational interactions across time and space. With a coder’s mindset and a physicist’s intuition, he integrates tools like Python, Mathematica, and AI-ML frameworks into his theoretical workflows 🔍🤖. His work bridges abstract mathematical constructs with data-driven approaches, making him a pioneer in blending astrophysics with computational intelligence. Yogesh doesn’t merely study the universe — he attempts to decode its very blueprint through mathematical harmony and scientific creativity ✨📐.

🏅 Awards and Honors

While formal accolades may still be unfolding, Yogesh Bhardwaj’s contributions have already been recognized through the publication of influential research papers in journals like Astrophysics and Space Science and Communications in Theoretical Physics 📜. These works explore foundational ideas such as late-time cosmic acceleration and Chaplygin gas models, positioning him as a rising voice in the theoretical cosmology community 🚀. His dedication to academic mentorship on platforms like Chegg and Course Hero was consistently appreciated through positive learner feedback and top ratings 🌟. Completing competitive online certifications — such as “100 Days of Code: Python Pro Bootcamp” and “Data-Driven Astronomy” — highlights his commitment to continuous growth and mastery 🧠. Though early in his career, his scholarly impact, digital teaching footprint, and analytical rigor forecast a future ripe with recognition, innovation, and leadership in science and research 🏆📈.

📚 Publications Top Note 

1. Title: Matter creation cosmology with generalized Chaplygin gas

  • Authors: Yogesh Bhardwaj, C.P. Singh

  • Year: 2024

  • Citation Count (as of now): 4

  • Source: Astrophysics and Space Science, Vol. 369, Issue 1, Article 2

  • Summary:
    This paper investigates a cosmological model that incorporates matter creation processes within a framework governed by the generalized Chaplygin gas (GCG) equation of state. The GCG acts as a unifying candidate for dark energy and dark matter. By considering non-conservation of particle number due to matter creation, the model shows accelerated cosmic expansion consistent with current observations. Thermodynamic and dynamical system analyses confirm the model’s viability for late-time acceleration.

2. Title: Constraining the variable generalized Chaplygin gas model in matter creation cosmology

  • Authors: Yogesh Bhardwaj, C.P. Singh

  • Year: 2024

  • Citation Count (as of now): 1

  • Source: Communications in Theoretical Physics, Vol. 76, Issue 10, Article 105403

  • Summary:
    This study introduces a variable generalized Chaplygin gas (VGCG) model where the GCG parameter evolves with cosmic time. The authors integrate this evolving VGCG into a matter creation framework and use observational data to constrain model parameters. The results show that this model better fits cosmic acceleration data compared to constant GCG models. Stability analysis and observational bounds further validate the framework’s consistency with ΛCDM-like behavior.

3. Title: Late cosmic acceleration by matter creation cosmology in modified gravity

  • Authors: Yogesh Bhardwaj, C.P. Singh

  • Year: 2025

  • Citation Count (as of now): 0 (early 2025 publication)

  • Source: Annals of Physics, Article ID: 170128

  • Summary:
    This paper explores matter creation cosmology in the context of modified gravity theories, particularly focusing on how such models explain the late-time acceleration of the universe without invoking a cosmological constant. The work incorporates a generalized gravitational action and evaluates cosmological parameters, showing that the interaction between matter creation and modified gravity leads to a smooth transition from deceleration to acceleration. The findings highlight the potential of modified gravity combined with thermodynamic matter creation to resolve dark energy issues.

🌟 Conclusion

Yogesh Bhardwaj is not just a research cosmologist  he is a mathematical dreamer, computational architect, and a seeker of the universe’s hidden code 🧬🌠. Driven by curiosity and powered by intellect, he exemplifies what it means to think deeply, model boldly, and solve meaningfully. His journey, rooted in rigorous education and diverse research experience, reflects a blend of classic scientific methodology and next-generation tech adoption 🔄📚. Yogesh brings creativity to complex cosmological systems, aiming not just to observe the universe but to comprehend its language. Off the research grid, his human side — lover of cricket, music, and mountaintop philosophies — grounds him in passion and humility. As he continues charting new intellectual territories, Yogesh is poised to become a luminary in applied cosmology, reshaping how we understand time, space, and the quantum threads connecting them 🌌🚀📊.

Dr. Can Okan Altan | Preservation | Best Researcher Award

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Dr. Can Okan Altan | Preservation | Best Researcher Award

Researcher at Sinop University, Department of Seafood Processing Technology, Turkey

Dr. Can Okan Altan, a dedicated Assistant Professor at Sinop University, excels in the field of aquatic food processing and preservation. His academic trajectory—rooted in fisheries and aquatic products—has evolved into specialized research on modified atmosphere packaging, enzymatic restructuring, and innovative preservation techniques for fish like trout and Turkish salmon. With numerous national projects under his belt, Dr. Altan contributes significantly to food safety, quality assurance, and sustainable seafood technologies. His leadership roles, including Deputy Director of a scientific research center, underline his commitment to research-driven impact. From hands-on microbiological analysis to advanced spectroscopic methods, he blends traditional knowledge with modern solutions. 🐟🧪📚

Professional Profile 

🎓 Education

Dr. Altan’s academic journey began at Karadeniz Technical University with a Bachelor’s in Aquatic Products (2009), followed by a Master’s (2014) and Ph.D. (2020) in Fishing and Processing Technology from Sinop University. His graduate research explored ionizing radiation for fish preservation and the application of microbial transglutaminase in rainbow trout meatballs under modified atmosphere—highlighting both innovation and industrial relevance. Guided by Prof. Dr. Hülya Turan, his theses established a strong foundation in enzymology and food packaging. His commitment to specialized research in aquatic technology stands out, reflecting a blend of biological sciences with food engineering. 🎓🧬🐠

🧪 Professional Experience

Starting as a Research Assistant in 2012, Dr. Altan’s decade-long association with Sinop University has culminated in his current role as Assistant Professor. His professional growth is marked by involvement in over a dozen national projects, ranging from the study of Black Sea whiting to smart labeling using onion-skin-derived pH indicators. His work integrates academic instruction—teaching microbiology and spectroscopy—to leading-edge research in fish product development, including sous vide and liquid smoke treatments. He now co-directs the Scientific and Technological Studies Center, driving interdisciplinary innovation and applied science. 🧑‍🏫🔬📈

🔬 Research Interests

Dr. Altan focuses on aquatic product preservation, enzymatic restructuring, packaging innovation, and food quality tracking technologies. His projects investigate microbial safety, sensory properties, shelf-life optimization, and the development of smart packaging indicators. From nanoemulsion-infused vacuum packaging to combining sous vide with liquid smoke, his interdisciplinary approach merges biochemistry, marine biology, and food technology. His ongoing research includes exploring the environmental benefits of mussel farming and pH-sensitive indicators using natural extracts. Dr. Altan’s work advances both academic knowledge and real-world applications in sustainable seafood science. 🧪🌊🧫

🏆 Awards & Honors

Dr. Altan received recognition in 2012 through the University Knowledge Competition, affirming his early academic promise. His career achievements are embedded not just in accolades but in impactful collaborations and research outputs. He has consistently taken on key roles as principal investigator, advisor, and core researcher in government- and institution-funded projects. More importantly, his administrative appointment as Deputy Director (2024–2027) reflects institutional trust and leadership recognition. His courses in fish smoking and spectroscopic techniques add to his distinguished academic influence. 🏅📖💼

📚 Publications Top Note 

1. Synergistic effect of freezing and irradiation on Bonito Fish (Sarda sarda Bloch, 1793)

  • Authors: CO Altan, H Turan

  • Year: 2016

  • Citations: 20

  • Source: Journal of Food Protection, 79(12), 2136-2142

  • Summary: Investigates how combining freezing and gamma irradiation affects microbial load and quality traits of bonito fish. The dual treatment improved microbial safety while preserving sensory characteristics, offering a promising preservation method.

2. Influence of different essential oils on marinated anchovy (Engraulis encrasicolus L. 1758) during refrigerated storage

  • Authors: D Kocatepe, H Turan, CO Altan, I Keskin, A Ceylan, B Köstekli, et al.

  • Year: 2019

  • Citations: 18

  • Source: Food Science and Technology, 39(Suppl. 1), 255–260

  • Summary: Evaluates the effect of natural essential oils (e.g., thyme, clove) on the shelf life, microbiology, and sensory quality of marinated anchovy. Certain oils significantly enhanced preservation without chemical additives.

3. Effect of modified atmosphere packaging on the shelf life of rainbow trout (Oncorhynchus mykiss, Walbaum 1792) mince

  • Authors: D Kocatepe, H Turan, CO Altan, I Keskin, A Ceylan

  • Year: 2016

  • Citations: 17

  • Source: Food Science and Technology International, 22(4), 343–352

  • Summary: Explores how modified atmosphere packaging (MAP) extends the shelf life of trout mince. MAP with CO₂-rich gas mixtures delayed spoilage and retained nutritional quality during cold storage.

4. The sensory characteristics, nutritional profile and physical changes of the Atlantic bonito (Sarda sarda Bloch, 1793) gravlax: Effect of dill (Anethum graveolens) and garden rocket

  • Authors: CO Altan, B Köstekli, B Çorapci, MS İpar, D Kocatepe, H Turan

  • Year: 2022

  • Citations: 12

  • Source: International Journal of Gastronomy and Food Science, 28, 100490

  • Summary: Studies the development of gravlax from bonito fish using dill and rocket as curing agents. These herbs enhanced flavor, antioxidant activity, and maintained nutritional values while modifying the texture.

5. Preliminary investigation of the nutritional composition of two commercial fish species: Rainbow trout (Oncorhynchus mykiss) and Atlantic salmon (Salmo salar)

  • Authors: D Kocatepe, H Turan, B Köstekli, CO Altan, B Çorapci

  • Year: 2023

  • Citations: 10

  • Source: Journal of the Hellenic Veterinary Medical Society, 73(4), 4817–4826

  • Summary: Compares proximate composition, fatty acid profiles, and minerals of farmed rainbow trout and Atlantic salmon. Both species offer high-quality proteins and omega-3 fatty acids beneficial to human health.

6. Interaction between rancidity and organoleptic parameters of anchovy marinade (Engraulis encrasicolus L. 1758) include essential oils

  • Authors: H Turan, D Kocatepe, İ Keskin, CO Altan, B Köstekli, C Candan, A Ceylan

  • Year: 2017

  • Citations: 10

  • Source: Journal of Food Science and Technology, 54(10), 3036–3043

  • Summary: Focuses on the relationship between oxidative rancidity and sensory qualities in anchovy marinades treated with essential oils. Oils delayed lipid oxidation and improved taste profile.

7. Black Sea whiting: assessment of potential health benefits/risks and differences based on mineral concentrations of meat and roes

  • Authors: H Turan, CO Altan, D Kocatepe

  • Year: 2019

  • Citations: 9

  • Source: Turkish Journal of Agriculture-Food Science and Technology, 7(12), 2075–2082

  • Summary: Analyzes mineral levels in meat and roe of Black Sea whiting. While the fish is nutritious, care is needed regarding trace elements like cadmium. Highlights potential dietary contributions and safety considerations.

8. The Effect of Microbial Transglutaminase (MTGase) Enzyme on Physical, Sensorial and Nutritional Properties of Atlantic Salmon (Salmo salar Linnaeus, 1758) Meatballs

  • Authors: CO Altan, D Kocatepe, MS İpar, B Çorapcı, B Köstekli, H Turan

  • Year: 2023

  • Citations: 6

  • Source: Journal of Agricultural Faculty of Gaziosmanpasa University, 40(1), 41–49

  • Summary: Investigates the use of MTGase in forming fish meatballs. The enzyme improved textural and sensory properties while preserving nutritional value, suggesting suitability for processed seafood production.

9. Effect of the vacuum packaging on the shelf life of Lakerda

  • Authors: D Kocatepe, H Turan, CO Altan, G Göknar

  • Year: 2014

  • Citations: 6

  • Source: International Journal of Food Science Nutrition and Dietetics, 3(9), 157–159

  • Summary: Evaluates the shelf life of traditional salted bonito (lakerda) under vacuum packaging. Results show extended preservation and improved organoleptic qualities compared to non-packaged counterparts.

10. Effect of different thawing methods on the quality of bonito (Sarda sarda, Bloch 1793)

  • Authors: H Turan, D Kocatepe, CO Altan, G Göknar

  • Year: 2015

  • Citations: 5

  • Source: Ukrainian Food Journal, 4(3), 460–466

  • Summary: Compares thawing methods (refrigerator, water, microwave) on quality parameters like drip loss, texture, and taste of bonito. Refrigerated thawing yielded the best results in maintaining fish quality.

11. A Comprehensive Investigation of Tenderization Methods: Evaluating the Efficacy of Enzymatic and Non-Enzymatic Methods in Improving the Texture of Squid Mantle—A Detailed Study

  • Authors: CO Altan, D Kocatepe, B Çorapcı, B Köstekli, H Turan

  • Year: 2024

  • Citations: 4

  • Source: Food and Bioprocess Technology, 17, 3999–4024

  • Summary: Reviews various tenderization approaches for squid meat, comparing enzymes like papain and mechanical methods. Identifies optimal techniques for softening squid texture while preserving flavor and nutrients.

12. Quality of lakerda (dry salted bonito) made with different technics in Sinop region

  • Authors: H Turan, CO Altan, D Kocatepe, A Ceylan

  • Year: 2015

  • Citations: 4

  • Source: Ukrainian Journal of Food Science, 3, 1–6

  • Summary: Investigates traditional and modern methods for preparing lakerda in Sinop. Assesses their effects on taste, texture, and microbiological quality. Traditional methods showed better flavor but required hygiene improvements.

13. Soğukta saklanan tüketime hazır midyelerin (Mytilus galloprovincialis L. 1819) besin kompozisyonu ve kalite kriterlerinin incelenmesi

  • Authors: H Turan, D Kocatepe, CO Altan, İ Erkoyuncu

  • Year: 2012

  • Citations: 4

  • Source: Hatay Gıda Kongresi, p. 364

  • Summary: Examines nutritional values and spoilage indicators of ready-to-eat mussels stored under cold conditions. Results provide insights for producers on maintaining freshness and meeting food safety standards.

🔚 Conclusion

In conclusion, Dr. Can Okan Altan stands out as a passionate an d innovative researcher in aquatic food science. His expertise spans quality control, smart packaging, and eco-friendly preservation essential pillars for future food systems. Backed by academic rigor, research diversity, and a commitment to practical outcomes, he continues to shape the future of fish product technology in Turkey and beyond. His ability to merge scientific depth with industrial relevance makes him a valuable academic leader and a promising candidate for excellence in research recognition. 🌟🇹🇷🔍

Prof. Dr. Rômulo Santos | Applied Mathematics | Best Academic Researcher Award

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Prof. Dr. Rômulo Santos | Applied Mathematics | Best Academic Researcher Award

Postdoctoral Researcher at Santa Cruz State University, Ilhéus, Bahia, Brazil

Dr. Rômulo Damasclin C. Santos 🇧🇷 is an accomplished applied mathematician and fluid dynamics specialist whose career bridges deep theoretical insight with computational precision. With a Ph.D. in Applied Mathematics from the University of Porto 🎓 and postdoctoral research at the prestigious Instituto Tecnológico de Aeronáutica (ITA) 🔬, he seamlessly integrates mathematical rigor with practical modeling. His passion lies in deciphering real-world physical phenomena using tools such as Partial and Integro-Differential Equations, Complex Analysis, and Fluid Dynamics 💨. He has held diverse teaching and research roles across Brazil, including UESC and UEMS, contributing significantly to academic development nationwide 📘. A published innovator, Dr. Santos has developed original computational methods like HODIM and Hybrid Adaptive DRM, alongside expertise in C++, Python, and MATLAB 💻. Actively involved in peer-review and editorial duties, his interdisciplinary approach is anchored in innovation, collaboration, and mathematical excellence. 🧠🌐

Professional Profile 

🎓 Education

Dr. Santos’s educational path reflects an unyielding drive for mastery in applied mathematics and engineering. He earned his Ph.D. in Applied Mathematics from the University of Porto (Portugal) in 2018, focusing on fluid dynamics through advanced numerical and analytical models 📘. Prior to that, he completed an M.Sc. in Mechanical Engineering at the Federal University of Itajubá (UNIFEI), specializing in flow machines and thermofluid systems 🌪️. His academic journey began with a Bachelor’s degree in Mathematics at the Federal University of Acre (UFAC), where he concurrently explored fractal geometry and object-oriented programming 🧮💻. Currently, he is further expanding his scientific breadth through postdoctoral research in Physics at ITA, one of Brazil’s foremost institutions in science and technology 🔬. This multifaceted academic background underpins his ability to approach problems from both abstract and applied angles.

👨‍🏫 Professional Experience

Dr. Santos has amassed a wealth of academic and research experience across Brazil’s most respected institutions 🏛️. He currently serves as a Postdoctoral Research Fellow at UESC and concurrently holds a professorship in Mathematics at UEMS, demonstrating his dual commitment to research and education 📚. His past roles include teaching positions at Federal Institutes (Santa Catarina, Acre), Mato Grosso State University, and UVERSO University Center, often within the engineering or mathematics departments 🧠. Whether substituting or leading research, he brought clarity and innovation to diverse academic environments. With more than a decade of academic engagement, he has nurtured student talent, advanced new methodologies, and contributed to institutional development nationwide. His dynamic roles—spanning from mathematical modeling to engineering theory—reflect a professional identity grounded in flexibility, excellence, and forward-thinking mentorship. 🎓🧪

🔬 Research Interests

Dr. Santos’s research is a fusion of theoretical depth and computational elegance 🧬. His core interests revolve around Fluid Dynamics, Turbulence Modeling, and Heat Transfer, particularly in incompressible Newtonian fluids 🌊. His toolkit includes advanced methods like Immersed Boundary Method (IBM), Smoothed-Particle Hydrodynamics (SPH), and LES, all tailored to simulate real-world chaotic flows. He integrates Partial, Integral, and Integro-Differential Equations to decipher the complex interplay in dynamical systems 🔁. Using programming languages such as C++, Python, and MATLAB, he develops original algorithms, including the High-Order Dynamic Integration Method (HODIM) and Hybrid Adaptive DRM for large-scale systems 🖥️. His mathematical framework draws from Complex Analysis, Functional Analysis, and Numerical Methods, making his contributions valuable across engineering, physics, and applied mathematics domains. His ambition is to model nature’s complexities through computation and logic, offering insights that cross traditional disciplinary boundaries. 🔗🌌

🏅 Awards and Honors

Dr. Santos has earned national and international recognition through prestigious academic engagements and editorial responsibilities 🌍. His Ph.D., validated in Brazil by UFRGS, exemplifies international academic excellence 🎓. As a reviewer and editorial board member for several renowned journals—such as Journal of Applied Fluid Mechanics, Brazilian Journal of Physics, and ASTES Journal—he contributes to the global dissemination of scientific knowledge 📖. Moreover, his commitment to innovation is officially recognized through computer program registrations with INPI, Brazil’s national patent authority 🏷️. He is a respected member of elite professional bodies, including the Brazilian Society for Applied and Computational Mathematics (SBMAC), Brazilian Mathematical Society (SBM), and the International Association of Engineers and Computer Scientists (IAENG) 🤝. These affiliations, coupled with his published innovations, affirm his role as a forward-thinking thought leader in applied mathematics and engineering systems.

📚 Publications Top Note 

1. Hypermodular Neural Operators: Ramanujan-Kantorovich Synthesis in Sobolev Approximation Theory

  • Authors: Rômulo D. C. dos Santos & Jorge H. de Oliveira Sales

  • Year: 2025 (July 8)

  • Source: HAL Open Science (Preprint)

  • Citation: HAL ID: hal-05115451

  • Summary: This work proposes a fusion of Ramanujan summability concepts with Kantorovich-type neural operators to form “hypermodular” neural frameworks. It operates within Sobolev spaces and demonstrates superior convergence and approximation behavior, especially near boundaries. The authors establish convergence results and operator stability using Sobolev norms.

2. Symmetrized Neural Network Operators in Fractional Calculus: Caputo Derivatives, Asymptotic Analysis, and the Voronovskaya–Santos–Sales Theorem

  • Authors: Rômulo D. C. dos Santos, Jorge H. de Oliveira Sales, Gislan S. Santos

  • Year: 2025 (June 30)

  • Source: Axioms (MDPI), Journal Article

  • DOI: 10.3390/axioms14070510

  • Summary: This article introduces symmetrized neural network operators tailored to fractional calculus and Caputo derivatives. It develops a new asymptotic theorem named after the authors, offering enhanced convergence analysis for fractional neural networks. Applications include fractional signal processing and modeling of dissipative systems.

3. Innovations in Neural Approximation: Uniting Symmetrized Kantorovich-Ramanujan Operators within Sobolev Spaces

  • Authors: Rômulo D. C. dos Santos & Jorge H. de Oliveira Sales

  • Year: 2025 (June 23)

  • Source: HAL Open Science (Preprint)

  • Citation: HAL ID: hal-05115451 (version 1)

  • Summary: A foundational version of the unified Kantorovich-Ramanujan operator framework for neural networks. This work extends approximation theory in Sobolev spaces using Ramanujan-style summability corrections and operator symmetrization.

4. Advancing Neural Approximation: The Role of Kantorovich-Ramanujan-Santos-Sales Operators in Modern Computation

  • Authors: Rômulo D. C. dos Santos & Jorge H. de Oliveira Sales

  • Year: 2025 (May 26)

  • Source: Zenodo (CERN), Preprint

  • DOI: 10.5281/ZENODO.15514812

  • Summary: Introduces a new family of operators combining Kantorovich-Ramanujan theory with neural networks, emphasizing boundary regularization, smoothness control, and numerical stability. A Voronovskaya-type expansion is derived for these operators.

5. Stochastic Fractional Neural Operators: A Symmetrized Approach to Modeling Turbulence in Complex Fluid Dynamics

  • Authors: Rômulo D. C. dos Santos & Jorge H. de Oliveira Sales

  • Year: 2025 (May 21)

  • Source: arXiv (Computer Science > Machine Learning)

  • DOI: 10.48550/ARXIV.2505.14700

  • Summary: This paper explores stochastic extensions of fractional neural operators applied to fluid turbulence. By incorporating symmetrized neural kernels and stochastic perturbations, the authors model uncertainty and chaotic behavior in turbulent flow systems.

6. Anomalous Gradients in AI: Multivariate Fractional Calculus Unifying Landau Inequalities and Deep Operator Stability

  • Author: Rômulo D. C. dos Santos

  • Year: 2025 (May 18)

  • Source: Zenodo (CERN), Preprint

  • DOI: 10.5281/ZENODO.15454789

  • Summary: Investigates the connection between multivariate fractional calculus and gradient stability in AI. The study proposes a new operator framework addressing anomalous gradients through generalizations of Landau inequalities.

7. Extension of Symmetrized Neural Network Operators with Fractional and Mixed Activation Functions

  • Authors: Rômulo D. C. dos Santos & Jorge H. de Oliveira Sales

  • Year: 2025 (May 11)

  • Source: The Journal of Engineering and Exact Sciences

  • DOI: 10.18540/jcecvl11iss1pp21662

  • Summary: This work extends neural approximation theory using fractional and mixed-type activation functions (like q-deformed and inverse polynomial activations). It presents a new Jackson-type inequality and convergence analysis.

8. Neural Network Operators for the New Era of Fractional Calculus: Bridging Analysis and Artificial Intelligence Systems

  • Author: Rômulo D. C. dos Santos

  • Year: 2025 (April 6)

  • Source: Zenodo (CERN), Preprint

  • DOI: 10.5281/ZENODO.15163347

  • Summary: Introduces neural operators that operate natively in the fractional calculus domain. Sets a foundational framework unifying AI learning mechanisms with fractional integral and differential operators.

9. Beyond Traditional Approximation: Advanced Voronovskaya-Damasclin Theory for Neural Network Approximation in Fractional Calculus

  • Author: Rômulo D. C. dos Santos

  • Year: 2025 (March 30)

  • Source: Zenodo (CERN), Preprint

  • DOI: 10.5281/ZENODO.15109088

  • Summary: Provides theoretical extensions of Voronovskaya’s theorem into the realm of neural approximation using fractional operators. Establishes sharp asymptotic error bounds for fractional neural network functionals.

10. Bifurcations, Stability and Numerical Analysis of Turbulent Flow (Bidimensional)

  • Author: Rômulo D. C. dos Santos

  • Year: 2025 (April 17)

  • Source: Observatório de la Economía Latinoamericana

  • DOI: 10.55905/oelv23n4-125

  • Summary: Focuses on the use of fractional and numerical methods to model bifurcation behavior in two-dimensional turbulent flows. Combines theory from dynamical systems with neural-based numerical solvers.

🧩 Conclusion

Dr. Rômulo Damasclin C. Santos is a polymath in the truest sense—merging theory, simulation, and real-world application into a cohesive scientific narrative 🔄. His journey from the Amazon to Europe and back to Brazil’s top academic circles reflects determination, intellectual courage, and innovation 🌎. As an educator, he has shaped minds across Brazil; as a researcher, he has expanded the boundaries of what’s possible in fluid dynamics and numerical modeling 💡. His multidisciplinary mindset enables him to tackle complex problems with originality, backed by robust mathematical foundations and computational fluency. In a world increasingly driven by scientific modeling and simulation, Dr. Santos stands out as a pioneering figure ready to lead the charge in engineering mathematics and technological advancement 🚀📊.

Assoc. Prof. Dr. Siriprapa Kaeajaeng | Biomedical Science | Women Researcher Award

Published on by Physicist Particle

Assoc. Prof. Dr. Siriprapa Kaeajaeng | Biomedical Science | Women Researcher Award

Lecturer at Chiang Mai University, Thailand

Assoc. Prof. Dr. Siriprapa Kaeajaeng is a distinguished academic in the field of radiologic technology, currently serving as a lecturer at the Department of Radiologic Technology, Faculty of Associated Medical Sciences, Chiang Mai University, Thailand. With a career deeply rooted in biomedical sciences and radiological innovation, she brings a vibrant mix of scientific curiosity and teaching excellence to the forefront. Her academic journey, from a Bachelor’s in Radiological Technology 🧲 to a Doctorate in Biomedical Science 🧬, showcases her unwavering commitment to medical imaging advancement and public health. Her work encompasses groundbreaking research, student mentorship, and contributions to diagnostic radiology education. Passionate about radiological safety, imaging innovation, and radiobiology, she continues to influence the next generation of technologists and researchers. 🎯 Dr. Siriprapa stands as a beacon of knowledge, embodying the fusion of academic excellence, scientific discovery, and compassionate healthcare service. 💡👩‍⚕️📖

Professional Profile 

🎓 Education 

Dr. Siriprapa Kaeajaeng’s educational pathway is a testament to her scholarly rigor and passion for the biomedical sciences. She began her academic pursuit with a Bachelor of Science in Radiological Technology from Naresuan University in 2008 🎯, laying a strong foundation in imaging and clinical practice. Driven to deepen her expertise, she earned her Master of Science in Medical Radiation Sciences from Chiang Mai University in 2012 📡, delving into advanced radiological methods and technologies. Her academic zenith came in 2015, when she obtained a Ph.D. in Biomedical Science from Chiang Mai University 🧠, where she focused her research on radiobiology and the biological effects of medical radiation. Her comprehensive academic background fuses theory, practice, and research in medical radiation sciences, positioning her as a well-rounded and highly knowledgeable educator. 📚 Her continuous academic progression reflects a genuine commitment to enhancing the science and safety of radiological practices. 🔬👩‍🎓🧬

👩‍🏫 Professional Experience 

Assoc. Prof. Dr. Siriprapa has built an impressive academic and professional career within Chiang Mai University, where she currently lectures in the Department of Radiologic Technology. Her work blends instruction, research supervision, and curriculum development, significantly enriching the academic environment 🌱. Known for her dynamic lectures and hands-on clinical guidance, she mentors both undergraduate and graduate students, preparing them for the complex demands of the radiologic field 🧲. In addition to teaching, she collaborates on interdisciplinary research projects, facilitates academic workshops, and participates in academic conferences nationally and internationally 🌍. She is also engaged in community health initiatives, leveraging her knowledge to promote radiation safety awareness. Her career is a harmonious blend of classroom innovation, lab-based inquiry, and professional service, making her a respected figure among colleagues and students alike. 👩‍⚕️📖 Her work fosters not only scientific growth but also ethical and patient-centered radiological practices. 💬🩻📈

🔬 Research Interests 

Dr. Siriprapa’s research is deeply embedded in the cutting-edge intersections of radiobiology, radiologic technology, and medical imaging innovation. Her key interests include the biological impact of ionizing radiation, imaging optimization for clinical applications, and the development of radiological protocols that enhance patient safety without compromising diagnostic quality 🔍. She is particularly focused on biomedical responses to radiation exposure, contributing to the field’s understanding of dose management and radioprotective strategies 🛡️. Her research also explores the integration of AI and machine learning into radiological practices to streamline diagnosis and minimize errors 📊. By participating in interdisciplinary collaborations, she connects clinical insights with technological advancements. Her work not only adds to the academic literature but also provides tangible benefits in hospitals and medical centers. 🧠📷 Through rigorous inquiry and innovation, Dr. Siriprapa continues to make impactful contributions that are shaping the future of radiologic science. 🚀🧬📸

🏅 Awards and Honors 

Throughout her career, Dr. Siriprapa has been recognized for her dedication to research excellence, teaching quality, and contributions to the radiologic sciences community. Her academic distinction has earned her commendations from Chiang Mai University and various scientific bodies, celebrating her research on biomedical responses to radiation exposure and her efforts in student engagement 🎓. As a rising leader in medical radiation science, she has received invitations to speak at prominent conferences and has been honored for her impactful publications 📚. She is also frequently involved in peer reviews and scientific committees, showcasing her influence within the academic ecosystem. Her awards not only signify personal achievement but also reflect the broader societal value of her work in improving medical imaging and healthcare standards 📈. These accolades affirm her reputation as a trailblazer whose efforts are advancing the quality, safety, and innovation of radiologic education and practice. 🌟🎗️📜

📚 Publications Top Note 

1. High transparency La₂O₃–CaO–B₂O₃–SiO₂ glass for diagnostic X-ray shielding material application

  • Authors: S. Kaewjaeng, S. Kothan, W. Chaiphaksa, N. Chanthima, et al.

  • Year: 2019

  • Citations: 279

  • Source: Radiation Physics and Chemistry, Volume 160, Pages 41–47

  • Summary: This work developed lanthanum-based borosilicate glasses for diagnostic X-ray shielding. The glasses demonstrated high optical transparency and effective attenuation of X-rays, making them promising for safe, transparent radiation protection applications in medical diagnostics.

2. Development of BaO–ZnO–B₂O₃ glasses as a radiation shielding material

  • Authors: N. Chanthima, J. Kaewkhao, P. Limkitjaroenporn, S. Tuscharoen, S. Kothan, et al.

  • Year: 2017

  • Citations: 237

  • Source: Radiation Physics and Chemistry, Volume 137, Pages 72–77

  • Summary: This paper explores the radiation shielding potential of barium and zinc borate glasses. The incorporation of BaO and ZnO improves the gamma ray shielding effectiveness, offering a lead-free alternative for protective glass materials.

3. Luminescence characteristics of Dy³⁺ doped Gd₂O₃–CaO–SiO₂–B₂O₃ scintillating glasses

  • Authors: J. Kaewkhao, N. Wantana, S. Kaewjaeng, S. Kothan, H. J. Kim

  • Year: 2016

  • Citations: 156

  • Source: Journal of Rare Earths, Volume 34, Issue 6, Pages 583–589

  • Summary: The study focuses on dysprosium-doped glasses for scintillation. The glasses exhibit promising luminescence under UV excitation, showing potential as scintillators for X-ray or radiation detection applications.

4. Influence of Er³⁺ ion concentration on optical and photoluminescence properties of Er³⁺-doped gadolinium–calcium–silica–borate glasses

  • Authors: C. R. Kesavulu, H. J. Kim, S. W. Lee, J. Kaewkhao, N. Wantana, S. Kothan, et al.

  • Year: 2016

  • Citations: 130

  • Source: Journal of Alloys and Compounds, Volume 683, Pages 590–598

  • Summary: Erbium-doped glasses were studied for optical amplifier applications. Photoluminescence intensity increased with Er³⁺ concentration until concentration quenching occurred. The materials are relevant for infrared laser and photonic devices.

5. Effect of BaO on optical, physical and radiation shielding properties of SiO₂–B₂O₃–Al₂O₃–CaO–Na₂O glasses system

  • Authors: S. Kaewjaeng, J. Kaewkhao, P. Limsuwan, U. Maghanemi

  • Year: 2012

  • Citations: 118

  • Source: Procedia Engineering, Volume 32, Pages 1080–1086

  • Summary: This study investigates how BaO addition enhances gamma-ray shielding ability in silicate-based glasses. Increasing BaO content improved the linear attenuation coefficient and density without compromising optical clarity.

6. Spectroscopic investigations of Nd³⁺ doped gadolinium–calcium–silica–borate glasses for NIR emission at 1059 nm

  • Authors: C. R. Kesavulu, H. J. Kim, S. W. Lee, J. Kaewkhao, N. Wantana, E. Kaewnuam, et al.

  • Year: 2017

  • Citations: 112

  • Source: Journal of Alloys and Compounds, Volume 695, Pages 590–598

  • Summary: Neodymium-doped borosilicate glasses were evaluated for near-infrared emissions, focusing on laser material applications. The work analyzed spectral parameters and fluorescence behavior supporting use in photonic systems.

7. Energy transfer from Gd³⁺ to Sm³⁺ and luminescence characteristics of CaO–Gd₂O₃–SiO₂–B₂O₃ scintillating glasses

  • Authors: N. Wantana, S. Kaewjaeng, S. Kothan, H. J. Kim, J. Kaewkhao

  • Year: 2017

  • Citations: 111

  • Source: Journal of Luminescence, Volume 181, Pages 382–386

  • Summary: The work investigates energy transfer mechanisms from Gd³⁺ to Sm³⁺ ions in borosilicate glasses. It supports the development of Sm³⁺-activated scintillators for medical and nuclear imaging.

8. Mechanical and radiation shielding properties of flexible material based on natural rubber/Bi₂O₃ composites

  • Authors: S. Intom, E. Kalkornsurapranee, J. Johns, S. Kaewjaeng, S. Kothan, et al.

  • Year: 2020

  • Citations: 102

  • Source: Radiation Physics and Chemistry, Volume 172, Article 108772

  • Summary: A novel composite combining Bi₂O₃ and natural rubber was developed for flexible radiation shields. The material shows significant attenuation of X-rays and gamma rays, offering an eco-friendly alternative to traditional lead shielding.

9. Energy transfer based emission analysis of Eu³⁺ doped Gd₂O₃–CaO–SiO₂–B₂O₃ glasses for laser and X-ray detection material applications

  • Authors: N. Wantana, E. Kaewnuam, B. Damdee, S. Kaewjaeng, S. Kothan, H. J. Kim, et al.

  • Year: 2018

  • Citations: 84

  • Source: Journal of Luminescence, Volume 194, Pages 75–81

  • Summary: Europium-doped gadolinium borosilicate glasses were assessed for luminescence under X-ray and UV excitation. The emission properties suggest applications in laser and radiation detection systems.

10. Investigations of optical and luminescence features of Sm³⁺ doped Li₂O–MO–B₂O₃ (M = Mg/Ca/Sr/Ba) glasses mixed with different modifier oxides as orange light emitting materials

  • Authors: K. Kirdsiri, R. R. Ramakrishna, B. Damdee, H. J. Kim, S. Kaewjaeng, S. Kothan, et al.

  • Year: 2018

  • Citations: 77

  • Source: Journal of Alloys and Compounds, Volume 749, Pages 197–204

  • Summary: Sm³⁺ doped glasses with various alkaline earth modifiers were studied. The orange luminescence intensity varied with the modifier oxide, suggesting compositional tuning possibilities for lighting and display devices.

🧭 Conclusion 

Assoc. Prof. Dr. Siriprapa Kaeajaeng exemplifies the harmony of academic excellence, innovative research, and compassionate healthcare leadership. Her journey from student to accomplished educator and scientist reflects resilience, intellect, and a deep commitment to radiological advancement 🌐. With a strong educational background, notable professional experience, and a portfolio of impactful research, she continues to be a driving force in radiologic technology and biomedical science 🔬. Her work empowers students, informs policy, and elevates the standards of medical imaging. As she continues to explore new frontiers in radiation science and technology, her legacy is being etched in classrooms, laboratories, and medical institutions alike 🏥. Dr. Siriprapa’s vision, integrity, and passion set her apart as a role model and innovator in the field. Her contributions are not just academic—they are deeply human, aiming to enhance lives through knowledge, technology, and care. 💖📡👩‍⚕️

Dr Rajendra Patil | Chemistry | Excellence in Research Award

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Dr Rajendra Patil | Chemistry | Excellence in Research Award

Assistant Professor at M H Shinde Mahavidyalaya, Tisangi, India

Dr. Rajendra Pandurang Patil, a distinguished academician and gold-medalist 🥇 from GATE, is currently serving as an Assistant Professor of Chemistry at M. H. Shinde Mahavidyalaya, Tisangi, Kolhapur, he has consistently showcased brilliance from undergraduate to doctoral levels, achieving distinction in both B.Sc. and M.Sc., and earning his Ph.D. in 2012 with a focus on “Synthesis, Characterization and Applications of Mixed-Metal Oxides.” With 15 years of research and 13 years of teaching experience 📚, Dr. Patil has cultivated an impressive academic legacy. His contributions in advanced materials chemistry are echoed through 109 international publications and 4 granted patents 🧪. A stalwart in nanotechnology and energy materials, his scholarly excellence is reflected in a Google Scholar h-index of 22 and over 1700 citations 📈. A dedicated educator, innovator, and scientist, Dr. Patil continues to push the frontiers of applied and fundamental chemistry.

Professional Profile 

🎓 Education

Dr. Rajendra Patil’s academic journey is a remarkable story of perseverance and achievement 🏅. Starting with a first-class distinction in B.Sc. and M.Sc. in Inorganic Chemistry  from Shivaji University, Kolhapur, he went on to secure an exceptional GATE score of 89.66 at IIT Guwahati. His passion for material science drove him to complete his Ph.D. in 2012 under Prof. P. P. Hankare, focusing on mixed-metal oxides—vital compounds in catalysis and energy systems. Alongside these degrees, Dr. Patil also holds a certification in MS-CIT, showcasing his digital proficiency 🖥️. His early academic projects, such as synthesizing PbSe thin films, laid the groundwork for a robust research career. The depth and continuity in his academic pursuits have positioned him as a thought leader in material and nanoscience, blending classical chemical principles with modern applications 🌡️.

👨‍🏫 Professional Experience

Dr. Patil brings over 13 years of dedicated teaching experience as a permanent Assistant Professor since March 2013 📘. Prior to this, he honed his analytical and practical skills during his 2-year tenure as a laboratory chemist in the industrial sector 🧪. His research journey began as a Junior Research Fellow on two major UGC and DAE-BRNS projects from 2008 to 2012, focusing on functional oxides and nanomaterials. With a comprehensive background that bridges academic theory and industrial practice, Dr. Patil’s pedagogy is enriched by real-world relevance and cutting-edge innovation. His commitment to students and research has made him an integral figure in the chemistry community of Kolhapur. Whether guiding undergraduates or contributing to national seminars, his influence resonates across laboratories, classrooms, and scholarly platforms 📖. His interdisciplinary approach makes him a bridge between classical chemistry education and modern research development 🌍.

🔍 Research Interests

Dr. Patil’s research specialization lies in the dynamic fields of ferrites, mixed-metal oxides, and their futuristic applications 🚀. His work spans nanocomposites used in photocatalysis, supercapacitor development, and magnetic hyperthermia—a promising therapy for cancer treatment. With a clear emphasis on applied material science, his innovations address global challenges in renewable energy and health. Notably, his patents reflect breakthroughs in nanoparticle-based cancer diagnostics, surface-functionalized ferrites for hyperthermia, and composite materials for energy storage. These fields align with global priorities in sustainable development and nanotechnology 🔋🧬. His publications—over 100 in international journals—demonstrate the scholarly impact and real-world relevance of his research. Dr. Patil is also a prolific presenter, with over 40 seminars to his name, continuously advocating for the integration of chemistry into practical, life-enhancing solutions 🌐. His work is a fusion of scientific curiosity and societal need, driven by precision, ethics, and innovation.

🏅 Awards and Honors

Among Dr. Patil’s many accolades, the GATE Gold Medal 🎖️ stands out as a testament to his academic excellence. His receipt of four granted patents speaks volumes about his contributions to chemical innovation and real-world applications. With over 1700 citations and a Scopus h-index of 22, Dr. Patil has earned significant recognition in the global research community 📊. He has been instrumental in multiple government-funded research projects and has continuously engaged with national and international seminars. His work in magnetic nanomaterials for cancer therapy and sustainable energy solutions marks him as a pioneering figure in applied chemistry. These achievements are not only a recognition of his research output but also a reflection of his dedication to advancing science in meaningful and impactful ways. His honors affirm his position as one of the emerging leaders in the field of material science and nanotechnology 🔬.

📚 Publications Top Note 

1. Title: Enhanced photocatalytic degradation of methyl red and thymol blue using titania–alumina–zinc ferrite nanocomposite
Authors: PP Hankare, RP Patil, AV Jadhav, KM Garadkar, R Sasikala
Year: 2011
Citations: 213
Source: Applied Catalysis B: Environmental
Summary: This study focuses on the photocatalytic degradation of organic dyes using a composite nanomaterial made from titania, alumina, and zinc ferrite. It demonstrates effective treatment of water pollutants like methyl red and thymol blue under light irradiation.

2. Title: Magnetic and dielectric properties of nanophase manganese-substituted lithium ferrite
Authors: PP Hankare, RP Patil, UB Sankpal, SD Jadhav, IS Mulla, KM Jadhav, and others
Year: 2009
Citations: 123
Source: Journal of Magnetism and Magnetic Materials
Summary: This research explores the magnetic and dielectric behavior of lithium ferrite materials that are substituted with manganese. The study highlights their potential in applications involving magnetic storage and high-frequency devices.

3. Title: Gas sensing properties of magnesium ferrite prepared by co-precipitation method
Authors: PP Hankare, SD Jadhav, UB Sankpal, RP Patil, R Sasikala, IS Mulla
Year: 2009
Citations: 113
Source: Journal of Alloys and Compounds
Summary: The paper investigates the gas sensing performance of magnesium ferrite nanoparticles synthesized through the co-precipitation method. It demonstrates sensitivity to specific gases, indicating usefulness in sensor technology.

4. Title: Effect of sintering on photocatalytic degradation of methyl orange using zinc ferrite
Authors: SD Jadhav, PP Hankare, RP Patil, R Sasikala
Year: 2011
Citations: 90
Source: Materials Letters
Summary: This work analyzes how sintering temperature influences the photocatalytic degradation activity of zinc ferrite materials. It focuses on removing the dye methyl orange from wastewater, offering insights for optimizing material processing.

5. Title: Synthesis, structural and magnetic properties of different metal ion substituted nanocrystalline zinc ferrite
Authors: RP Patil, SD Delekar, DR Mane, PP Hankare
Year: 2013
Citations: 86
Source: Results in Physics
Summary: This study synthesizes and characterizes zinc ferrite nanoparticles substituted with various metal ions. The research evaluates their structural and magnetic properties, contributing to the understanding of ferrite-based nanomaterials.

6. Title: Investigation of structural and magnetic properties of nanocrystalline manganese substituted lithium ferrites
Authors: PP Hankare, RP Patil, UB Sankpal, SD Jadhav, PD Lokhande, and others
Year: 2009
Citations: 85
Source: Journal of Solid State Chemistry
Summary: This research explores the structural and magnetic characteristics of lithium ferrite materials substituted with manganese, aiming at enhancing their magnetic performance for advanced applications.

7. Title: Magnetic and dielectric studies of nanocrystalline zinc substituted Cu–Mn ferrites
Authors: PP Hankare, UB Sankpal, RP Patil, AV Jadhav, KM Garadkar, and others
Year: 2011
Citations: 83
Source: Journal of Magnetism and Magnetic Materials
Summary: This study presents a detailed investigation into the magnetic and dielectric properties of Cu–Mn ferrites modified with zinc, suggesting possible use in electronic devices.

8. Title: Synthesis and characterization of CoCrₓFe₂−ₓO₄ nanoparticles
Authors: PP Hankare, UB Sankpal, RP Patil, IS Mulla, PD Lokhande, NS Gajbhiye
Year: 2009
Citations: 66
Source: Journal of Alloys and Compounds
Summary: The article reports on the synthesis and structural analysis of cobalt-chromium substituted spinel ferrite nanoparticles, contributing to materials design for magnetic and catalytic purposes.

9. Title: Effect of sintering temperature on structural, magnetic properties of lithium chromium ferrite
Authors: RP Patil, PP Hankare, KM Garadkar, R Sasikala
Year: 2012
Citations: 65
Source: Journal of Alloys and Compounds
Summary: This work investigates how sintering temperature influences the microstructure and magnetic properties of lithium chromium ferrites, guiding optimal processing conditions.

10. Title: Synthesis, dielectric behavior and impedance measurement studies of Cr-substituted Zn–Mn ferrites
Authors: PP Hankare, RP Patil, KM Garadkar, R Sasikala, BK Chougule
Year: 2011
Citations: 65
Source: Materials Research Bulletin
Summary: The study examines the dielectric and impedance properties of chromium-substituted Zn–Mn ferrites, providing insights for their potential use in electronics and sensors.

✅ Conclusion

In summation, Dr. Rajendra Pandurang Patil is a well-rounded academician whose journey from a student in Kolhapur to a nationally recognized researcher exemplifies passion and persistence 💼. With a rich background in education, extensive research output, practical industrial experience, and pioneering contributions to nanoscience, he stands out as a deserving candidate for any Best Researcher Award 🏆. His intellectual curiosity, combined with a deep commitment to educational excellence and real-world application, positions him as a beacon of inspiration for aspiring scientists. Whether in the lab, classroom, or scholarly community, Dr. Patil embodies the values of innovation, integrity, and impact. As chemistry advances into new frontiers, his work continues to resonate—fueling progress and shaping the future of sustainable science 🌱🔬.

Prof. Marilyn E Noz |Physics |Best Researcher Award

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Prof. Marilyn E Noz|Physics |Best Researcher Award

Professor. Marilyn E Noz at New York University, United States

Dr. Marilyn E. Noz 🇺🇸, born June 17, 1939, in New York City 🗽, is a trailblazing physicist and educator whose pioneering work bridges theoretical physics and medical imaging. With a Ph.D. in Physics from Fordham University 🎓, she emerged as a powerful voice in nuclear medicine and radiological research. Serving NYU’s School of Medicine for over four decades 🏥, she rose from Assistant Professor to Professor Emerita and Research Professor. Her accolades include awards from renowned bodies like the Society of Nuclear Medicine and Radiological Society of North America 🏆. A licensed Medical Physicist and diplomate of multiple scientific boards, Dr. Noz is recognized globally for CT/SPECT fusion advancements and nuclear magnetic resonance insights 💡. Her dedication to education, research, and clinical innovation marks her as a luminary in the intersection of physics and medicine 🌟.

Professional Profile 

🎓 Education

Dr. Marilyn E. Noz’s academic path is as illustrious as her career. She graduated summa cum laude in Mathematics from Marymount College in 1961, setting a strong foundation in analytical thinking and scientific curiosity 🧮. She pursued both her M.S. and Ph.D. in Physics at Fordham University, completing them in 1963 and 1969 respectively ⚛️. Her commitment to academic excellence was recognized through numerous fellowships and scholarships, including the National Defense Education Act Fellowship and the New York State Regents Fellowship 🏅. This scholarly journey laid the groundwork for her later groundbreaking contributions to nuclear medicine and radiological science. Her educational philosophy continues to inspire aspiring physicists and medical professionals alike 📚.

👩‍🔬 Professional Experience

Dr. Noz’s professional journey spans prestigious institutions and critical innovations. Beginning as a professor at Marymount College in the 1960s, she shaped young scientific minds while holding leadership roles 👩‍🏫. Her career blossomed at New York University’s Department of Radiology, where she spent over three decades—from Assistant Professor to Research Professor and Professor Emerita 🏛️. She held concurrent roles at Tisch Hospital and Bellevue Hospital, enhancing clinical radiology practice. Her adjunct positions at Manhattan College and Iona College reflect her dedication to sharing knowledge across disciplines 🌐. Notably, she played a pivotal role in advancing nuclear medicine physics and medical imaging integration, leaving an indelible mark on academic and clinical settings 🧬.

🔬 Research Interest

Dr. Noz’s research traverses the dynamic interface between physics and medicine. Her primary focus lies in nuclear medicine physics, SPECT/CT fusion, and nuclear magnetic resonance 🧠. She is known for pioneering the integration of cross-sectional imaging modalities, improving diagnostic accuracy and patient care through novel imaging algorithms and data interpretation techniques 🖥️. Her work in radiation protection and computational physics has also made significant contributions to the safety and efficacy of imaging technologies ☢️. As a physicist deeply invested in translational science, Dr. Noz has published extensively and mentored future leaders in medical physics, bridging theoretical insight with clinical innovation seamlessly 🔗.

🏅 Awards and Honors

Throughout her distinguished career, Dr. Noz has received numerous prestigious awards celebrating her research excellence and innovation 🌟. Highlights include the Giovanni DiChiro Award for outstanding research in the Journal of Computer Assisted Tomography, and several Cum Laude honors from the Society of Computed Body Tomography 🧾. Her work in CT/SPECT fusion earned multiple scientific exhibit awards, showcasing her ingenuity in imaging science 🎖️. She was a finalist for the ComputerWorld-Smithsonian Institute Awards and honored with a Senior International Research Fellowship by the NIH’s Fogarty International Center 🌍. These accolades underscore her enduring impact and peer recognition across interdisciplinary fields 🧪.

📚 Publications Top Note 

1. Can Na¹⁸F PET/CT bone scans help when deciding if early intervention is needed in patients being treated with a TSF attached to the tibia: insights from 41 patients

⚛️ 2. Integration of Dirac’s efforts to construct a quantum mechanics which is Lorentz‑covariant

  • Authors: Young S. Kim, Marilyn E. Noz

  • Year: 2020

  • Citations: 1

  • Source: Symmetry

  • Summary: This paper synthesizes Dirac’s 1927, 1945, 1949, and 1963 efforts to reconcile quantum mechanics with Lorentz covariance. It explains his use of Gaussian localization, light-cone coordinates, “instant form,” and coupled oscillators to derive Lorentz group representations, ultimately yielding a Lorentz‑covariant harmonic oscillator framework Colab+3arXiv+3arXiv+3bohr.physics.berkeley.edu+11MDPI+11arXiv+11.

🦴 3. Accuracy and precision of a CT method for assessing migration in shoulder arthroplasty: an experimental study

🧬 4. Einstein’s E = mc² derivable from Heisenberg’s uncertainty relations

  • Authors: Sibel Başkal, Young S. Kim, Marilyn E. Noz

  • Year: 2019

  • Citations: 5

  • Source: Quantum Reports

  • Summary: This theoretical paper demonstrates that the Lie algebra of the Poincaré group (and thus mass–energy equivalence) can emerge naturally from Heisenberg’s uncertainty relations. Using harmonic oscillators and signal‑space group contractions (O(3,2) → Poincaré), they derive E = mc² Inspire+15MDPI+15arXiv+15ysfine.com+1arXiv+1.

📷 5. Are low‑dose CT scans a satisfactory substitute for stereoradiographs for migration studies? A preclinical test…

  • Authors: Eriksson T, Maguire GQ Jr, Noz M.E., Zeleznik M.P., Olivecrona H., Shalabi A., Hänni M.

  • Year: 2019

  • Citations: 13

  • Source: Acta Radiologica

  • Summary: The authors tested multiple low‑dose CT protocols in a hip phantom and a pilot patient, finding that selected protocols (≈0.70 mSv) provided migration measurement precision comparable to standard RSA, demonstrating CT’s promise as a lower-dose, reliable tool link.springer.com+15PubMed+15Colab+15Colab+1ous-research.no+1.

🔄 6. Poincaré symmetry from Heisenberg’s uncertainty relations

  • Authors: (Likely similar to above)

  • Year: 2019

  • Citations: 4

  • Source: Symmetry

  • Summary: This related work further details how expanding from one to two oscillators in the Heisenberg framework leads to the de Sitter group, which can be contracted to the Poincaré group. It highlights a structural derivation of spacetime symmetries using quantum uncertainty Colabysfine.com+1arXiv+1.

🦴 7. Motion analysis in lumbar spinal stenosis with degenerative spondylolisthesis: A feasibility study of the 3DCT technique comparing laminectomy versus bilateral laminotomy

  • Authors: Not fully listed

  • Year: 2018

  • Citations: 6

  • Source: Clinical Spine Surgery

  • Summary: This feasibility study used 3D CT motion analysis to compare two spinal decompression techniques. Although article details are limited, it evaluated kinematic differences following laminectomy and bilateral laminotomy.

🦴 8. Prosthetic liner wear in total hip replacement: a longitudinal 13‑year study with computed tomography

  • Authors: Not fully listed

  • Year: 2018

  • Citations: 7

  • Source: Skeletal Radiology

  • Summary: This long-term CT-based evaluation tracked in vivo liner wear in total hip replacements over 13 years, offering valuable longitudinal data on implant durability and wear behavior.

📘 9. New perspectives on Einstein’s E = mc²

  • Authors: (Not specified)

  • Year: (Not specified, presumably recent)

  • Citations: 1

  • Source: Book

  • Summary: Presents fresh theoretical insights and interpretations surrounding mass–energy equivalence. Likely synthesizes recent research building on Dirac and uncertainty-related frameworks.

🔄 10. Loop representation of Wigner’s little groups

  • Authors: Not listed

  • Year: 2017

  • Citations: 3

  • Source: Symmetry

  • Summary: Investigates representations of Wigner’s little groups (subgroups of the Lorentz group preserving particle momentum) via loop structures, contributing to our understanding of relativistic particle symmetries.

🧭 Conclusion

Dr. Marilyn E. Noz stands as a beacon of scientific integrity, academic rigor, and humanistic contribution to medicine and physics 🌈. Her legacy is reflected not only in her groundbreaking research but also in her mentorship, teaching, and service to institutions that shape healthcare innovation 🏥. Through her interdisciplinary expertise and visionary leadership, she helped transform diagnostic imaging, elevate standards in medical physics, and inspire generations of scientists 📈. Even in emerita status, her influence resonates through her publications, innovations, and the many professionals she has mentored. A true pioneer, Dr. Noz exemplifies what it means to blend intellect, compassion, and purpose into a lifetime of contribution 🙌.

Prof. Hwa Yaw Tam | Engineering | Best Researcher Award

Published on by Physicist Particle

Prof. Hwa Yaw Tam | Engineering | Best Researcher Award

Prof. Hwa Yaw Tam at The Hong Kong Polytechnic University , Hong Kong

Prof. Hwa Yaw TAM 🎓🔬, IEEE Life Fellow and OPTICA Fellow, is a visionary in photonics and optical fibre sensing. Currently Chair Professor of Photonics at The Hong Kong Polytechnic University 🇭🇰, he has spearheaded groundbreaking innovations in fibre-optic sensor systems for transportation 🚄, energy ⚡, and medical 👂 applications. With over 800 publications 📚 and 20 patents 🔖, he stands as the second most cited expert in fibre-optic sensing, boasting an H-index of 73. His trailblazing contributions span continents, from Hong Kong’s MTR to the Netherlands and Australia 🌍. A laureate of the Berthold Leibinger Innovationspreis 🏆 and multiple Geneva Invention awards, Prof. Tam’s legacy bridges academia, industry, and public safety. His work has also spun off seven photonics companies 🚀. With unwavering passion and pioneering spirit, Prof. Tam continues to illuminate the future of smart sensing and laser technologies 🔭.

Professional Profile 

🎓 Education

Prof. Hwa Yaw TAM embarked on his academic voyage at The University of Manchester, UK 🇬🇧, earning both his B.Eng in 1985 and Ph.D. in 1989 🎓. His early educational foundations laid the groundwork for a lifelong commitment to photonics and optical engineering. Specializing in electrical and electronic engineering, his doctoral studies fused rigorous theory with hands-on research in laser systems and fibre technologies 🔍. This dual emphasis cultivated a mindset driven by innovation and precision. The UK academic environment, rich in historical scientific achievement, greatly influenced his research ethos 🌐. Prof. Tam’s education not only equipped him with cutting-edge technical knowledge but also instilled in him a vision to translate science into impactful, real-world applications. Today, that foundation continues to echo through his advanced fibre-optic sensor innovations 🔬, standing as a beacon for future generations of engineers and scientists 📘💡.

🏛️ Professional Experience

Prof. Tam’s professional journey spans academia and industry in equal brilliance 🌠. He began his research career at GEC-Marconi Ltd. (London) between 1989–1993, delving into erbium-doped fibre amplifiers and laser systems 💡. He then joined The Hong Kong Polytechnic University in 1993, rising through the ranks from Lecturer to Chair Professor of Photonics. He also served as Head of the Electrical Engineering Department and was the Founding Director of the Photonics Research Centre (2000–2022) 🏫. Presently, he is Associate Director at PolyU’s Photonics Research Institute, spearheading interdisciplinary innovations. Prof. Tam’s work transcends traditional academia—his team has launched seven start-ups, catalyzing photonics-based solutions globally 🚀. His leadership has shaped fibre-optic sensing systems for cities and industries across Asia, Europe, and Australia, turning theoretical breakthroughs into operational systems in railways 🚉, energy grids 🔋, and hospitals 🏥, positioning him as a pivotal force in global smart sensing networks 🌐.

🔬 Research Interest

Prof. Tam’s research orbits around specialty optical fibres tailored for real-world sensor applications 🔍. His core interests span the design and fabrication of advanced fibre-optic systems that serve as digital sentinels in complex infrastructures 🧠. From structural health monitoring (SHM) to real-time railway diagnostics, his innovations help prevent failures before they occur ⚠️. His pioneering optical fibre networks have monitored everything from high-speed trains 🚆 to smart escalators and even cochlear implants for medical precision 👂. By embedding fibre Bragg gratings (FBGs) into intelligent sensing webs, he’s revolutionized predictive maintenance across industries. His group’s work is particularly transformative in railway monitoring, with deployment success stories in Hong Kong, Singapore, and the Netherlands 🌍. Always ahead of the curve, Prof. Tam’s research fuses AI 🤖, photonic engineering, and real-time analytics to create a safer, more connected world through light 🌈 and precision sensing technologies 📈.

🏅 Awards and Honors

Prof. Tam’s achievements are globally celebrated 🏆. In 2025, he won the Special Prize and Gold Medal at Geneva’s Invention Expo for a smart cochlear implant 👂🌟. In 2024, he secured another Gold Medal for lithium-ion battery health monitoring via FBG sensors 🔋. Earlier, in 2022, his intelligent escalator monitoring system earned him yet another Geneva Gold Award 🥇. The Berthold Leibinger Innovationspreis in 2014, among the world’s highest laser tech honors, recognized his work in wavelength-tunable laser sensing for railways 🚄. His team also received the President’s Award for Knowledge Transfer in 2022 at PolyU for creating AI-enhanced optical fibre networks 🌐. Further accolades include a Best Paper finalist at IEEE SENSORS 2016 📃. Each honor underscores Prof. Tam’s deep impact on laser technology, smart sensing, and translational engineering. His consistent award-winning contributions reflect a perfect blend of scientific creativity, societal value, and engineering excellence 💼🔬.

📚 Publications Top Note 

  1. Title: Enhanced Quasi-Distributed Accelerometer Array Based on ϕ-OTDR and Ultraweak Fiber Bragg Grating
    Authors: , , , …
    Year: 2023
    Citations: 6
    Source: IEEE Sensors Journal
    Summary: Proposes an enhanced accelerometer array using phase-sensitive optical time-domain reflectometry (ϕ-OTDR) and ultraweak fiber Bragg gratings for distributed vibration sensing, suitable for applications like structural health monitoring.

  1. Title: Label-Free DNA Detection Using Etched Tilted Bragg Fiber Grating-Based Biosensor
    Authors: , , , …
    Year: 2023
    Citations: 6
    Source: Sensors
    Summary: Describes a label-free biosensor using etched tilted fiber Bragg gratings to detect DNA without the need for fluorescent labels, enhancing sensitivity and simplicity in genetic diagnostics.

  1. Title: Recovery of a Highly Reflective Bragg Grating in DPDS-Doped Polymer Optical Fiber by Thermal Annealing
    Authors: , , , …
    Year: 2023
    Citations: 2
    Source: Optics Letters
    Summary: Demonstrates the recovery of degraded Bragg gratings in doped polymer optical fibers using thermal annealing, showing potential for longer lifespan and reusability in fiber-optic sensors.

  1. Title: Accident Risk Tensor-Specific Covariant Model for Railway Accident Risk Assessment and Prediction
    Authors: , , , …
    Year: 2023
    Citations: 8
    Source: Reliability Engineering and System Safety
    Summary: Introduces a tensor-based statistical model for accurately assessing and predicting accident risks in railway systems by incorporating covariant risk factors.

  1. Title: Polymeric Fiber Sensors for Insertion Forces and Trajectory Determination of Cochlear Implants in Hearing Preservation
    Authors: , , , …
    Year: 2023
    Citations: 10
    Source: Biosensors and Bioelectronics
    Summary: Presents polymeric fiber-optic sensors designed to measure insertion force and trajectory during cochlear implant surgeries, helping to preserve hearing by reducing inner ear trauma.

  1. Title: Miniature Two-Axis Accelerometer Based on Multicore Fiber for Pantograph-Catenary System
    Authors: , , , ,
    Year: 2023
    Citations: 8
    Source: IEEE Transactions on Instrumentation and Measurement
    Summary: Develops a compact fiber-based accelerometer capable of sensing in two axes, tailored for monitoring the dynamics of pantograph-catenary interactions in electric rail systems.

  1. Title: Ultraminiature Optical Fiber-Tip Directly-Printed Plasmonic Biosensors for Label-Free Biodetection
    Authors: , , , …
    Year: 2022
    Citations: 19
    Source: Biosensors and Bioelectronics
    Summary: Describes a highly miniaturized fiber-tip plasmonic biosensor fabricated via direct printing, enabling sensitive and label-free detection of biomolecules at the microscale.

  1. Title: Accelerated Pyro-Catalytic Hydrogen Production Enabled by Plasmonic Local Heating of Au on Pyroelectric BaTiO3 Nanoparticles
    Authors: , , , …
    Year: 2022
    Citations: 83
    Source: Nature Communications
    Summary: Reports a novel hydrogen production method using gold-decorated BaTiO₃ nanoparticles, where plasmonic heating enhances pyro-catalytic activity under mild conditions.

  1. Title: Biomechanical Assessment and Quantification of Femur Healing Process Using Fibre Bragg Grating Strain Sensors
    Authors: , , , …
    Year: 2022
    Citations: 5
    Source: Sensors and Actuators A: Physical
    Summary: Uses fiber Bragg grating strain sensors to monitor and quantify mechanical changes in the femur during bone healing, supporting better postoperative assessment.

  1. Title: Mach-Zehnder Interferometer Based Fiber-Optic Nitrate Sensor
    Authors: , , , ,
    Year: 2022
    Citations: Not listed
    Source: Optics Express
    Summary: Presents a Mach-Zehnder interferometer design using optical fiber for detecting nitrate concentrations in water, aiming at applications in environmental monitoring

🔚 Conclusion 

Prof. Hwa Yaw TAM is more than a scholar—he is a trailblazer in light-based sensing technologies 🌟. His career weaves together pioneering science, practical engineering, and impactful entrepreneurship 🌐. Through over 800 papers, 20 patents, and numerous awards, he has reshaped how the world monitors structural, environmental, and human conditions using optical fibres 💡. His real-world implementations—from monitoring city-wide railways to enabling hearing restoration—demonstrate how research can elevate safety, precision, and quality of life for millions 🌍. He continues to mentor future innovators and drive collaborative photonic research through his leadership roles at PolyU and the Photonics Research Institute. With vision, dedication, and humility, Prof. Tam stands as a guiding light for the global photonics community 🌠. His journey exemplifies how science, when paired with compassion and creativity, becomes a force for building a smarter, safer, and more sustainable world 🔗🌿.

Yuh-Ming Ferng | Nuclear Engineering | Best Researcher Award

Published on by Physicist Particle

Prof. Dr. Yuh-Ming Ferng | Nuclear Engineering | Best Researcher Award

Professor at Department of Engineering and System Science, Taiwan

Dr. Yuh-Ming Ferng 📘 is a distinguished scholar and seasoned expert in the realm of nuclear engineering, serving as a Professor at National Tsing Hua University (NTHU), Taiwan 🇹🇼. With an illustrious career that spans decades, his expertise envelops diverse themes like nuclear safety, two-phase flow simulation, CFD modeling, and more 🚀. Holding a Ph.D. in Nuclear Engineering from NTHU, his academic foundation is as solid as his scientific contributions 🧠. From simulating fire combustion scenarios to optimizing wind turbine designs 🌪️, Dr. Ferng’s research transcends traditional boundaries. He has climbed the academic ranks, from researcher to professor, backed by a commitment to energy innovation and system safety ⚛️. His extensive knowledge, paired with a relentless curiosity, positions him as a guiding force in nuclear science. Dr. Ferng’s work not only contributes to academic excellence but also to public safety and sustainable energy futures 🌍.

Professional Profile 

🎓 Education

Dr. Ferng’s academic journey began and flourished at National Tsing Hua University (NTHU) 🎓, where he earned both his B.S. and Ph.D. in Nuclear Engineering 📐. Between 1982 and 1990, he immersed himself in the foundational and advanced mechanics of nuclear systems, solidifying his technical prowess. His doctoral thesis, guided by Professors C.C. Chieng and C. Pan, explored the “Numerical Simulation of Rewetting Process” 🔬 — a topic pivotal to thermal-hydraulic safety in reactors. His commitment to theoretical depth and practical relevance was evident early on. This dual-degree trajectory at a premier institution cultivated his analytical thinking, experimental finesse, and numerical skills. His scholarly focus on complex heat transfer phenomena, fluid dynamics, and system modeling laid the groundwork for his future contributions across interdisciplinary energy research fields. With education as his launchpad, Dr. Ferng emerged well-equipped to tackle intricate engineering challenges with academic rigor and scientific creativity 📊.

🧑‍🔬 Professional Experience

Dr. Yuh-Ming Ferng’s career is a rich mosaic of academic, governmental, and research roles spanning over three decades ⏳. Beginning in 1990 at the Institute of Nuclear Energy Research as an Associate Scientist, he dedicated over a decade to nuclear power advancements. Transitioning to NTHU in 2005, he served as a Senior Researcher before becoming Assistant Professor in 2008, Associate Professor in 2010, and ultimately Professor in 2017 👨‍🏫. His trajectory reflects consistent excellence, marked by groundbreaking research in system simulation, fire dynamics, and corrosion modeling 🔥. Whether analyzing severe reactor accidents or refining thermal simulations for hypersonic flows, he has contributed deeply to academic literature and policy-enhancing technologies. Dr. Ferng’s leadership in nuclear safety and CFD research has left a lasting imprint on Taiwan’s energy infrastructure, establishing him as a dependable figure in both scholarly and practical engineering domains 🛠️.

🔬 Research Interests

Dr. Ferng’s research is a multidimensional landscape shaped by curiosity and purpose 🧭. He delves into nuclear reactor safety analysis, boiling heat transfer, and severe accident modeling — all vital to risk mitigation and reactor resilience 🔐. His expertise in CFD turbulence modeling aids in visualizing complex fluid behaviors, while his simulations on fire combustion and hypersonic flows illustrate his adaptive ingenuity 🔥💨. From fuel cell design to wind turbine optimization, his portfolio spans conventional and renewable energy systems 🌬️🔋. He has also made notable strides in understanding steam generator tube degradation and developing erosion-corrosion models for predictive maintenance. Recently, his focus on SMR (Small Modular Reactor) simulations and spent fuel disposal underscores a forward-thinking approach to sustainable nuclear solutions ♻️. Dr. Ferng’s interdisciplinary palette not only bridges theory and application but also shapes energy strategies for future generations 🚀.

🏆 Awards and Honors

Although specific honors are not listed in the current record, Dr. Yuh-Ming Ferng’s elevation through prestigious academic and research positions reflects a career laden with recognition and respect 🏅. His appointments to senior researcher roles and ultimately full professorship at NTHU are a testament to his academic impact, research leadership, and mentoring excellence 🎖️. He has earned the trust of Taiwan’s top scientific institutions through consistent contributions to nuclear safety and energy innovation. His published works and simulation studies likely received acclaim in conferences and scholarly forums, establishing his name among regional and global peers 📚. Recognition often comes not just in plaques or certificates, but in the influence one has in shaping policies, guiding students, and pushing the boundaries of knowledge — and Dr. Ferng’s career exemplifies all three ⭐. His ongoing work continues to earn admiration from academia, industry, and government collaborators alike.

📚 Publications Top Note 

  1. Title: Thermal Management Design for the Be Target of an Accelerator-Based Boron Neutron Capture Therapy System Using Numerical Simulations with Boiling Heat Transfer Models

    • Authors: Not listed

    • Year: 2025

    • Citations: 0

    • Source: Processes

    • Summary: Introduces a simulation-based design for cooling a beryllium (Be) target used in neutron therapy systems. It evaluates boiling heat transfer to ensure safe operation under high thermal loads.

  2. Title: Development of thermal‑hydraulic coupling model for deep‑geological disposal of high‑level radioactive wastes

    • Authors: Not listed

    • Year: 2024

    • Citations: 1

    • Source: Nuclear Engineering and Design

    • Summary: Proposes a coupled model integrating heat transfer and fluid flow to assess the long-term performance of geological repositories for high-level radioactive waste.

  3. Title: Numerical model for noise reduction of small vertical‑axis wind turbines

    • Authors: Not listed

    • Year: 2024

    • Citations: 2

    • Source: Wind Energy Science

    • Summary: Develops and validates a simulation tool aimed at identifying and reducing aerodynamic noise sources in small vertical-axis turbines.

  4. Title: Numerical prediction of the aerodynamics and aeroacoustics of a 25 kW horizontal axis wind turbine

    • Authors: Not listed

    • Year: 2024

    • Citations: 1

    • Source: Journal of Mechanics

    • Summary: Simulates airflow and sound emissions for a mid-sized horizontal-axis wind turbine, comparing predicted noise and performance with experimental results.

  5. Title: Development of computational methodology in simulating thermal responses of spent fuel in deep geological disposal

    • Authors: Not listed

    • Year: 2023

    • Citations: 2

    • Source: Nuclear Engineering and Design

    • Summary: Introduces a computational framework to model temperature evolution in spent nuclear fuel stored deep underground, accounting for decay heat and rock interactions.

  6. Title: Investigating effects of heating orientations on boiling heat transfer and bubble dynamics for pool boiling on downward facing heating surface

    • Authors: Not listed

    • Year: 2023

    • Citations: 1

    • Source: Nuclear Engineering and Design

    • Summary: Experimental and numerical study on how the orientation of a heating surface influences boiling efficiency and bubble behavior when the surface faces downward.

  7. Title: Experimental investigation of pool boiling heat transfer and bubble dynamics for the downward facing heating

    • Authors: Not listed

    • Year: 2022

    • Citations: 4

    • Source: Annals of Nuclear Energy

    • Summary: Reports lab experiments measuring boiling heat transfer rates and bubble detachment patterns on downward-facing surfaces.

  8. Title: Development of 3‑D numerical methodology to investigate transient characteristics of fuel temperature and hydrated residual water during drying process of dry storage system

    • Authors: Not listed

    • Year: 2022

    • Citations: 0

    • Source: Annals of Nuclear Energy

    • Summary: Presents a 3D transient model simulating temperature changes and moisture behavior in spent fuel canisters during drying operations before storage.

  9. Title: Localization and size estimation for breaks in nuclear power plants

    • Authors: Not listed

    • Year: 2022

    • Citations: 3

    • Source: Nuclear Engineering and Technology

    • Summary: Describes a method to detect the location and size of pipe breaks in nuclear reactors using sensor data and inverse modeling techniques.

  10. Title: Experimentally investigating bubble dynamics and pressure drop for bubbly upflow in a vertical annular channel

    • Authors: Not listed

    • Year: 2021

    • Citations: 4

    • Source: Annals of Nuclear Energy

    • Summary: Examines two-phase bubbly flow in vertical channels, measuring pressure losses and bubble behavior—relevant for nuclear reactor cooling systems.

🌟 Conclusion

Dr. Yuh-Ming Ferng stands as a beacon of excellence in nuclear engineering, with a unique ability to blend theoretical insight and practical implementation 🌐. His scholarly rigor, coupled with a vision for sustainable and safe energy, has made him an integral part of Taiwan’s scientific community 🔍. From developing intricate simulation models to training future engineers, his work resonates across disciplines and generations. His influence goes beyond classrooms and labs — it touches policy, public safety, and environmental resilience 🌱. Dr. Ferng’s evolving research on SMRs, fire safety, and spent fuel management showcases his relevance in addressing today’s most pressing energy challenges. In a world navigating energy transitions and climate imperatives, experts like Dr. Ferng are essential guides 🔋. As a professor, mentor, and researcher, his career is both a legacy in the making and a blueprint for innovation-driven engineering 🚀.

Shih Chang Lee | Particle Physics | Best Researcher Award

Published on by Physicist Particle

Dr. Shih Chang Lee | Particle Physics | Best Researcher Award

Academician at Institute of Physics, Academia Sinica, Taiwan

Shih-Chang Lee 🎓, born on May 25, 1952, is a revered Taiwanese physicist 🧠 with a prolific career in both experimental and theoretical particle physics. As Emeritus Distinguished Research Fellow at Academia Sinica and professor at National Tsing Hua University and National Central University, he has pioneered Taiwan’s participation in global physics collaborations 🌍. His leadership in the CDF experiment contributed to the discovery of the top quark 🧬, and he played a founding role in the AMS and TEXONO projects, bringing Taiwan to the forefront of space and neutrino physics 🚀. Lee’s theoretical insights on monopoles and dyons in gravity theory have also inspired future cosmological explorations 🌌. With honors like the Enrico Fermi Award and fellowship in TWAS 🌟, his legacy radiates across continents and disciplines. Lee stands as a trailblazer 👣, continually elevating Taiwan’s scientific impact through visionary experiments, international leadership, and groundbreaking discoveries in fundamental physics.

Professional Profile 

🎓 Education 

Shih-Chang Lee’s educational journey began with a B.S. in Physics from National Taiwan University in 1974 🎓, marking his early affinity for fundamental sciences. His passion led him across the globe to Princeton University, where he earned a Ph.D. in Physics in 1980 📘. Immersed in elite academic environments like the Institute for Advanced Study and ITP at SUNY Stony Brook, Lee developed a solid theoretical foundation while engaging with global thought leaders 🧠. His early exposure to world-class physics institutions helped shape a visionary mindset that would later guide Taiwan into major international collaborations. This global-academic pathway ignited a spark that positioned him not only as a scholar but also as an institution-builder. From theory-rich halls in New Jersey to the future collider blueprints in Taiwan, Lee’s educational milestones served as the launchpad for a lifetime of pioneering research, reinforcing the profound value of cross-cultural, cross-institutional academic excellence 🌐.

👨‍🔬 Professional Experience 

Spanning over four decades, Shih-Chang Lee’s professional journey is a masterclass in academic leadership and scientific contribution 🧪. Beginning as a research associate at elite centers like IAS and SUNY, he returned to Taiwan in 1983 to join the Institute of Physics, Academia Sinica, ascending from Associate to Distinguished Research Fellow and Deputy Director 🏛️. He held pivotal roles such as Program Director at the National Science Council, Taiwan’s representative in global physics bodies like ICFA, ACFA, and the International Linear Collider Steering Committee 🌍. Notably, he led Taiwan’s participation in landmark experiments: CDF, AMS, TEXONO, and ATLAS at CERN. His strategic foresight helped establish Taiwan’s only Tier-1 computing center in the Worldwide LHC Grid 💻. As CEO of the Academia Sinica Grid Center, he seamlessly merged high-energy physics with data science. Lee’s career is a luminous blend of scientific ingenuity, policy influence, and global research diplomacy 🌐.

🔭 Research Interests 

Lee’s research portfolio spans experimental high-energy physics, astroparticle physics, and theoretical field theory, making him a polymath of modern particle physics 🧲. His experimental pursuits began with the CDF experiment, where he contributed to the top quark’s discovery ⚛️. He spearheaded Taiwan’s participation in the AMS space spectrometer, uncovering high-energy radiation anomalies and redefining cosmic ray models ☄️. Lee also originated the TEXONO neutrino project, achieving world-best results on the electron-neutrino magnetic moment — a milestone in Taiwan’s physics history. At CERN’s ATLAS, his team provided cutting-edge optical readout systems and helped develop Taiwan’s data processing hub for the LHC 🔍. Theoretically, Lee proposed the use of stochastic quantization for lattice gauge theory and classified magnetic monopole and dyon solutions in higher-dimensional gravity, sparking future explorations into cosmology 🌠. His research ethos combines rigor, foresight, and technological innovation to push the boundaries of fundamental knowledge in both Earth-bound and cosmic dimensions 🌌.

🏅 Awards and Honors 

Dr. Shih-Chang Lee’s illustrious career has earned him a constellation of accolades, affirming his stature as one of Asia’s most accomplished physicists 🌟. His early work garnered the National Science Council’s Outstanding Research Award (1986, 1988) and the Chung Shan Prize (1987) 🥇. He was named Fellow of the Physical Society of R.O.C. (1995) and received the Chuang Shou Geng Prize the same year 🏆. His international acclaim soared with the 2010 Enrico Fermi Award — a prestigious recognition from Italy’s Fermi Center for excellence in physics. In 2010, he was inducted as an Academician of Academia Sinica, Taiwan’s highest scholarly honor 🎖️. In 2013, he joined the ranks of Fellows at The World Academy of Sciences (TWAS) 🌐. These honors are not just milestones; they reflect his groundbreaking research, global influence, and lifelong commitment to pushing the frontier of knowledge in physics and beyond 🚀.

📚 Publications Top Note 

1. Measurement of the top quark mass with the ATLAS detector using tt̄ events with a high transverse momentum top quark

  • Authors: ATLAS Collaboration

  • Year: 2025

  • Source: Physics Letters B,

  • Summary: This study measures the top quark mass using events where one top quark has high transverse momentum (pₜ), which improves precision due to better modeling and reduced background. A novel template fit approach is employed, achieving a competitive result with reduced systematic uncertainties.

2. Observation of VVZ production at √s = 13 TeV with the ATLAS detector

  • Authors: ATLAS Collaboration

  • Year: 2025

  • Citations: 1

  • Source: Physics Letters B,

  • Summary: First observation of diboson-plus-Z production (VVZ, where V = W or Z bosons) in proton-proton collisions at √s = 13 TeV. The analysis uses full Run 2 data and applies multivariate techniques to distinguish signal from background, confirming Standard Model predictions.

3. An implementation of neural simulation-based inference for parameter estimation in ATLAS

  • Authors: ATLAS Collaboration

  • Year: 2025

  • Source: Reports on Progress in Physics, IOPscience

  • Summary: Introduces a deep learning technique—simulation-based inference (SBI)—for parameter estimation in particle physics. The method is demonstrated on toy models and ATLAS-like scenarios, showing promise in reducing computational loads compared to traditional fitting.

4. Search for tt̄H/A → tt̄tt̄ production in pp collisions at √s = 13 TeV with the ATLAS detector

  • Authors: ATLAS Collaboration

  • Year: 2025

  • Source: European Physical Journal C, Springer

  • Summary: Searches for beyond-the-Standard-Model (BSM) scalar or pseudoscalar Higgs bosons decaying into four top quarks. No significant excess is observed, and upper limits are set on production cross-sections.

5. Measurement of off-shell Higgs boson production in the H → ZZ → 4ℓ decay channel using a neural simulation-based inference technique*

  • Authors: ATLAS Collaboration

  • Year: 2025

  • Source: Reports on Progress in Physics, IOPscience

  • Summary: Applies SBI methods to measure the off-shell Higgs signal in 4-lepton final states, helping to constrain the Higgs boson total width. Results align with Standard Model expectations.

6. Reconstruction and identification of pairs of collimated τ-leptons decaying hadronically using √s = 13 TeV pp collision data with the ATLAS detector

  • Authors: ATLAS Collaboration

  • Year: 2025

  • Source: European Physical Journal C, Springer

  • Summary: Describes novel techniques for identifying boosted hadronically decaying τ-lepton pairs, crucial for high-mass resonance searches. Machine learning algorithms improve efficiency and background rejection.

7. Observation of W±W±W∓ Production in Pb+Pb Collisions at √sNN with the ATLAS Detector

  • Authors: ATLAS Collaboration

  • Year: 2025

  • Citations: 2

  • Source: Physical Review Letters, APS

  • Summary: First observation of triple W-boson production in heavy-ion collisions, demonstrating the potential of LHC heavy-ion data to probe electroweak sector in extreme environments.

🔚 Conclusion 

Shih-Chang Lee’s career is a luminous beacon in the world of particle physics — a rare synthesis of visionary leadership, rigorous research, and international collaboration 🌠. His life’s work established Taiwan as a significant contributor to global high-energy physics, bridging scientific communities across continents. From discovering top quarks and decoding cosmic rays, to theorizing magnetic monopoles and fostering scientific infrastructure, Lee has reshaped Taiwan’s role in both experimental and theoretical domains 🔄. His deep commitment to education, mentorship, and institution-building continues to inspire the next generation of physicists 📘👨‍🏫. With unwavering passion and cross-disciplinary impact, Lee exemplifies the transformative power of curiosity, collaboration, and perseverance. As an architect of Taiwan’s modern physics landscape and a venerated voice in international science, his legacy is etched into the very fabric of fundamental research — spanning the particles of the atom to the mysteries of the cosmos 🧬🌌.