Yan Zhang – Computational Materials – Best Researcher Award

Posted on by AMO Physics

Ms. Yan Zhang embarked on her academic path with a deep passion for materials science, focusing particularly on the theoretical foundations of material behavior. Her strong academic background and dedication to scientific research led her to specialize in Computational Materials science, an increasingly vital area in advanced materials research. With a keen interest in crystallography and electronic structure, her early studies laid the groundwork for her advanced research in scintillator materials, specifically Bismuth Silicate (BSO) crystals.

💼 Professional Endeavors

Ms. Zhang’s professional journey is centered around the application of first-principles calculations to explore the physical and chemical properties of materials. As a researcher with a solid understanding of simulation methods and AI-assisted modeling, she has investigated the growth mechanisms of large-sized BSO crystals, including the impact of rare-earth ion doping on their performance. Her professional endeavors focus on optimizing materials for high-tech applications in Computational Materials, with particular relevance to optoelectronics and particle detection.

🔬 Contributions and Research Focus

Ms. Yan Zhang’s research focus lies in the Computational Materials domain, where she applies first-principles calculations to understand and enhance the functionality of scintillator materials. Her theoretical analysis of the crystal structure and Mulliken charges of BSO crystals doped with Tm³⁺ ions has provided deep insights into how doping influences conductivity and covalency. By breaking through the bottleneck in large-scale crystal growth technology and proposing models that clarify the regulation of dual-readout performance, she has made notable scientific and technical contributions that bridge the gap between theory and industrial practice.

🌍 Impact and Influence

The impact and influence of Ms. Zhang’s work extend both academically and industrially. Her paper published in Chemical Physics Impact has received recognition for its innovative methodology and valuable findings in Computational Materials research. Her research provides a framework for further exploration of BSO crystals in dual-readout calorimeters, influencing both scientific inquiry and the development of cutting-edge optoelectronic and high-energy detection technologies. Her findings also offer practical guidance for industrial-scale crystal manufacturing.

🏆Academic Cites

Ms. Yan Zhang's work has become a reliable reference point for researchers working on scintillator materials and high-performance crystals. Her contributions have been cited for their originality, depth, and practical applications, especially in the context of first-principles modeling and rare-earth doping. Her work in Computational Materials continues to resonate across both academic circles and applied research labs, confirming her growing influence in the field.

🌟 Legacy and Future Contributions

With a strong foundation in materials science and advanced computational techniques, Ms. Zhang is poised to become a leading contributor to the future of Computational Materials. Her legacy will be defined by her pioneering work on BSO crystals and the innovative application of AI and simulation in crystal growth optimization. She aims to continue driving forward the frontiers of research, fostering industrial upgrades and offering sustainable solutions in scintillation materials for advanced technologies. Her future prospects include mentoring young researchers, expanding interdisciplinary collaborations, and translating theoretical research into real-world applications.

📝Computational Materials

Ms. Yan Zhang's groundbreaking research in Computational Materials has introduced new pathways in the optimization of scintillator crystals using AI-assisted modeling and first-principles calculations. Her work continues to strengthen the foundation of Computational Materials science through its industrial relevance and academic rigor. Future innovations in Computational Materials are anticipated to benefit greatly from her continued contributions and visionary outlook.

Notable Publication

📝Preparation and surface morphology analysis of near stoichiometric lithium tantalate crystals by the vapour transfer equilibrium method

Authors: J. Si, X. Xiao, Y. Huang, C. Yang, X. Zhang

Journal: Journal of Crystal Growth

Year: 2025

Citations: 0

📝Crystal structure and Mulliken charge analysis of Gd³⁺-doped bismuth silicate

Authors: Y. Zhang, X. Xiao, Y. Huang, T. Tian, H. Shen

Journal: Materialia

Year: 2025

Citations: 1

📝First-Principles Calculations of the Optical Properties of Bi₄Si₃O₁₂:RE (RE = Ho³⁺, Tb³⁺, Eu³⁺, Gd³⁺, Sm³⁺, Tm³⁺) Crystals

Authors: Y. Huang, X. Xiao, T. Tian, H. Shen

Journal: Crystals

Year: 2025

Citations: 0

📝Highly efficient orange luminescence in Sn²⁺-doped Cs₂AgInCl₆ double perovskite with a large Stokes shift

Authors: J. Guo, Y. Peng, Y. Liu, Y. Fang

Journal: Journal of Materials Chemistry C

Year: 2025

Citations: 0

📝Eu³⁺-doped bismuth silicate crystal structure and Mulliken charge analysis

Authors: Y. Zhang, X. Xiao, Y. Huang, T. Tian, H. Shen

Journal: Acta Crystallographica Section C: Structural Chemistry

Year: 2024

Citations: 0

📝Study on the optical properties of Sm³⁺-doped bismuth silicate crystals based on first principles

Authors: Y. Huang, X. Xiao, Y. Zhang, T. Tian, H. Shen

Journal: Materials Research Express

Year: 2024

Citations: 1

Anoop Srivastava – Liquid Crystal Display – Best Researcher Award 

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Dr. Anoop Srivastava began his academic journey at the University of Allahabad, India, where he developed a solid foundation in physics. He earned his B.Sc. (Physics, Electronics, and Mathematics) with First Division in 1997, followed by an M.Sc. in Physics with a Specialization in Electronics in 1999, securing First Division with 67.44% marks. Demonstrating strong research potential early on, he qualified GATE-2001 in Physics with an 82.19 percentile. He culminated his early academic career with a Ph.D. in Physics in 2005, where he authored a thesis titled "Impedance Spectroscopy of Liquid Crystals", marking the beginning of his lifelong engagement with liquid crystal research and its applications in Liquid Crystal Display technologies.

💼 Professional Endeavors

Dr. Srivastava's professional path reflects a rich blend of academic leadership and international research exposure. Currently serving as an Associate Professor at the Institute of Engineering and Technology, Dr. Rammanohar Lohia Avadh University, Ayodhya, since August 2019, he has previously held academic positions at Nehru Gram Bharti Deemed University and SRM University. Notably, he completed two Postdoctoral Research Fellowships at Chonbuk National University, South Korea, contributing significantly to nanotechnology and polymer-nano science. In his administrative roles, he has served as Head of Department, Coordinator for national outreach programs (IIRS-ISRO, Virtual Labs), and played key roles in curriculum development and academic governance.

🔬 Contributions and Research Focus

Dr. Srivastava has made pioneering contributions in the area of Liquid Crystal Display research, particularly focusing on carbon nanotube and nanomaterial-doped liquid crystals. His research investigates the dielectric, optical, electrical, and thermodynamical properties of these materials to enhance their performance in energy-saving display devices. He has led several research projects funded by the Department of Science & Technology (DST), Government of India, and Directorate of Higher Education, Uttar Pradesh, focusing on advanced nanocomposite liquid crystals for Liquid Crystal Display applications. His work merges physics with real-world innovations in display technologies.

🌍 Impact and Influence

Dr. Anoop Srivastava’s work has had a considerable impact both nationally and internationally. He has been recognized with a Young Scientist Fellowship from DST, New Delhi, and received a Certificate of Appreciation from Chonbuk National University for his research contributions. His efforts in Liquid Crystal Display innovation earned him the Bronze Medal in 2022 from the Indian Liquid Crystal Society. His memberships in renowned bodies like Vigyan Bharti, International Liquid Crystal Society, and Indian Liquid Crystal Society highlight his stature in the scientific community.

🏆Academic Cites

Dr. Srivastava’s research contributions are well-regarded in the academic community, with numerous citations of his work related to nanomaterials and liquid crystals. His findings are frequently referenced in studies focusing on next-generation Liquid Crystal Display systems and energy-efficient devices. His publication portfolio, built over two decades of active research, serves as a foundational resource in the evolving landscape of display physics.

🌟 Legacy and Future Contributions

Dr. Anoop Srivastava’s legacy lies in bridging fundamental physics with applied technology, particularly in the Liquid Crystal Display domain. He continues to mentor Ph.D. scholars, including one recently awarded in 2024 and another currently under supervision. His future contributions are aimed at exploring nano-enhanced liquid crystal systems, optimizing them for sustainable and high-performance display devices. As a scholar, administrator, and mentor, his influence will continue to resonate through the advancements in both academia and industry.

📝Liquid Crystal Display

Through decades of dedicated research, Dr. Anoop Srivastava has significantly advanced the science behind Liquid Crystal Display technology. His innovative use of nanomaterials and focus on electrical, optical, and morphological properties of liquid crystals have transformed this field. Dr. Srivastava’s work in Liquid Crystal Display systems continues to shape modern energy-saving technologies and inspire future research directions.

Notable Publication

📝Effect of silver nanoparticles dispersed in nematic liquid crystal for display applications

Authors: A.K. Srivastava, Anoop Kumar; A. Kumar, Anil

Journal: Journal of Molecular Liquids

Year: 2025

Citations: 0

📝Analysis of dielectric parameters in paraelectric-ferroelectric biphasic region of antiferroelectric liquid crystal mixture

Authors: A.K. Srivastava, Anoop Kumar; A. Kumar, Anil; P.K. Tripathi, Pankaj Kumar; R. Gautam, Ratindra; V. Singh, Vijay

Journal: Indian Journal of Physics

Year: 2024

Citations: 0

📝Hydrogen energy: Addressing challenges and exploring future prospects

Authors: A.K. Shukla, Ajay Kumar; R. Gautam, Ratindra; S. Chaudhary, Shivani; S. Singh, Sindhu; P.K. Maurya, Pramod Kumar

Type: Book Chapter

Citations: 0

📝Enhancement of birefringence for liquid crystal with the doping of ferric oxide nanoparticles

Authors: P.K. Tripathi, Pankaj Kumar; P.D. Singh, Pratap Dharmendra; T.K. Yadav, Tarun Kumar; A.K. Srivastava, Anoop Kumar; Y.S. Negi, Yuvraj Singh

Journal: Optical Materials

Year: 2023

Citations: 18

📝Dielectric and electrooptical properties of hockey-stick-shaped liquid crystal with a negative dielectric anisotropy

Authors: P.T. Dang, Phuc Toan; A.K. Srivastava, Anoop Kumar; E.J. Choi, E. Joon; J. Lee, Jihoon

Journal: Current Applied Physics

Year: 2021

Citations: 4

📝CaLa₂ZnO₅:Gd³⁺ phosphor prepared by sol-gel method: Photoluminescence and electron spin resonance properties

Authors: V. Singh, Vijay; V. Natarajan, Venkataraman; N.S. Singh, N. Shanta; Y. Kwon, Young-whan; G. Lakshminarayana, Gandham

Journal: Optik

Year: 2020

Citations: 8

Yan He – Single Particle Tracking – Best Researcher Award 

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Prof. Yan He began his academic journey with a Bachelor of Science degree in Chemistry from the prestigious PEKING UNIVERSITY in 1995. His passion for analytical chemistry led him to the UNIVERSITY OF IOWA, where he earned his Ph.D. in 2001. These formative years were marked by a strong foundation in chemical analysis and instrumentation, which laid the groundwork for his future research trajectory. During his Ph.D., he developed a deep interest in advanced imaging techniques, eventually leading to his specialization in Single Particle Tracking and optical spectroscopy.

💼 Professional Endeavors

Following his doctoral studies, Prof. Yan He pursued postdoctoral training under the mentorship of the renowned Dr. E. S. Yeung at IOWA STATE UNIVERSITY. This period was critical in honing his expertise in high-resolution spectroscopy and fluorescence microscopy. In 2005, he joined the College of Chemistry and Chemical Engineering at Hunan University as a faculty member, where he established his research program. A decade later, he transitioned to Tsinghua University, one of China’s leading institutions, further elevating his academic and professional stature. His work has consistently pushed the boundaries of Single Particle Tracking and plasmonic imaging technologies.

🔬 Contributions and Research Focus

Prof. He’s research has significantly advanced the field of optical microscopy and spectroscopy. His primary focus is on Single Particle Tracking, particularly the temporal-spatial behavior of nanoparticle probes in complex environments. He has contributed to the development of novel plasmonic imaging techniques that allow researchers to visualize and quantify molecular interactions at the nanoscale. His work is not only methodologically innovative but also crucial for understanding dynamic processes in chemical and biological systems.

🌍 Impact and Influence

The IMPACT of Prof. Yan He’s research is profound and far-reaching. His contributions have shaped the development of cutting-edge imaging technologies used in both fundamental research and applied sciences. His expertise in Single Particle Tracking has positioned him as a thought leader in nanoscale imaging. He continues to influence a global network of collaborators, students, and interdisciplinary researchers who apply his methods to investigate phenomena in chemistry, biology, and materials science.

🏆Academic Cites

Prof. He’s scholarly work has been widely cited in high-impact journals, reflecting the significance of his scientific contributions. His studies on Single Particle Tracking and plasmonic imaging have become essential references for researchers working in nanotechnology and analytical chemistry. The broad citation of his publications attests to his authority in the field and his ongoing contribution to the evolution of advanced imaging technologies.

🌟 Legacy and Future Contributions

Looking forward, Prof. Yan He is poised to continue leading innovations in Single Particle Tracking and plasmonic imaging. His future research will likely delve deeper into real-time monitoring of molecular dynamics in increasingly complex environments, expanding the frontiers of analytical chemistry and nanoscience. His legacy will be defined by both his technological contributions and his role in training the next generation of scientists who will further these advancements.

📝Single Particle Tracking

Prof. Yan He's pioneering research in Single Particle Tracking has redefined the capabilities of nanoscale imaging, offering new insights into the behavior of individual nanoparticles. His innovative use of Single Particle Tracking in plasmonic imaging has advanced both analytical and biological applications. As a trailblazer in Single Particle Tracking, Prof. He continues to inspire and lead transformative changes in microscopy and spectroscopy.

Notable Publication

📝Physics-informed deep learning for stochastic particle dynamics estimation

Authors: Zhang, Yongyu; Zhu, Junlun; Xie, Hao; He, Yan

Journal: Proceedings of the National Academy of Sciences of the United States of America

Year: 2025

Citations: 0

📝Self-assembled monolayer boosts the air-stability and electrochemical reversibility of O3-type layered oxides for sodium-ion batteries

Authors: He, Yan; Zhang, Lei; Liu, Hongguang; Yan, Zichao; Zhu, Zhiqiang

Journal: Journal of Materials Chemistry A

Year: 2025

Citations: 0

📝Aqueous Zinc-Ion Batteries with Boosted Stability and Kinetics under a Wide Temperature Range

Authors: Zhang, Lei; Han, Yu; Geng, Yaheng; Yan, Zichao; Zhu, Zhiqiang

Journal: Angewandte Chemie International Edition in English

Year: 2025

Citations: 1

📝Highly fluorescent polyethyleneimine protected Au8 nanoclusters: One-pot synthesis and application in hemoglobin detection

Authors: Lu, Fengniu; Yang, Hongwei; Yuan, Zhiqin; Lü, Chao; He, Yan

Journal: Sensors and Actuators B: Chemical

Year: 2019

Citations: 39

📝A Novel Color Modulation Analysis Strategy through Tunable Multiband Laser for Nanoparticle Identification and Evaluation

Authors: Cao, Xuan; Lei, Gang; Feng, Jingjing; Wen, Xiaodong; He, Yan

Journal: Analytical Chemistry

Year: 2018

Citations: 12

Wen Wen – Bose-Einstein Condensate – Best Researcher Award 

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Associate Professor Dr. Wen Wen began her academic journey at East China Normal University, Shanghai, where she earned both her Bachelor of Science in Physics and her Ph.D. in Theoretical Physics. Her early academic pursuits reflect a strong foundation in fundamental physics, with a deep interest in quantum mechanics and particle theory. This educational background laid the groundwork for her specialization in the complex and emerging field of Bose-Einstein Condensate research, positioning her for a career dedicated to theoretical advancements in quantum systems.

💼 Professional Endeavors

Dr. Wen has held a longstanding academic position at Hohai University. From 2010 to 2014, she served as an Assistant Professor in the Department of Mathematics and Physics. Since 2014, she has been an Associate Professor in the College of Mechanics and Engineering Science. Her professional endeavors have spanned interdisciplinary domains, combining mathematics, physics, and engineering principles to explore novel quantum phenomena, particularly in the study of Bose-Einstein Condensate systems. Her teaching and mentoring have also contributed significantly to academic excellence within the university.

🔬 Contributions and Research Focus

Dr. Wen's research focuses primarily on Bose-Einstein Condensate systems, theoretical quantum mechanics, and nonlinear dynamics. She has contributed to the theoretical modeling of ultra-cold atomic gases and quantum field behaviors in condensed matter physics. Her work enhances the understanding of quantum phase transitions, coherence properties, and soliton structures in BEC systems. These contributions have not only added value to fundamental theoretical physics but have also informed experimental approaches in ultracold quantum gases.

🌍 Impact and Influence

Dr. Wen Wen's influence extends across academic and research communities in China and beyond. Through her research and academic service, she has played a vital role in shaping curricula and fostering a deeper understanding of quantum mechanics among students and peers. Her work on Bose-Einstein Condensate phenomena has been recognized in academic circles, influencing both theoretical frameworks and experimental inquiries. She stands as a role model for young physicists, particularly women in STEM fields.

🏆Academic Cites

Dr. Wen's publications have garnered academic citations that highlight the relevance and impact of her work in quantum physics. Her theoretical models and findings on Bose-Einstein Condensate systems have been cited by researchers investigating quantum coherence, vortex dynamics, and non-linear Schrödinger equations. Her citation record reflects the importance of her research in advancing the understanding of quantum states of matter.

🌟 Legacy and Future Contributions

As Dr. Wen Wen continues her academic journey, her legacy will be built upon her dedication to teaching, mentoring, and advancing the field of quantum theoretical physics. Her future contributions are expected to focus on further elucidating the properties of Bose-Einstein Condensate systems, especially in exploring interactions under external potentials and non-equilibrium conditions. She is poised to remain a key figure in theoretical physics, inspiring a new generation of physicists through both her research and academic leadership.

📝Bose-Einstein Condensate

Dr. Wen Wen's research on Bose-Einstein Condensate phenomena has significantly deepened the understanding of quantum coherence and low-temperature physics. Her continued work in Bose-Einstein Condensate theory provides vital insights into quantum state dynamics and contributes meaningfully to the broader field of condensed matter physics. With future studies, her exploration of Bose-Einstein Condensate behavior is expected to influence both theoretical development and experimental validation.

Notable Publication

📝Propagation of sound and supersonic bright solitons in superfluid Fermi gases in BCS-BEC crossover

Authors: W. Wen, S.Q. Shen, G. Huang

Journal: Physical Review B

Year: 2010

Citations: 47

📝Dynamics of dark solitons in superfluid Fermi gases in the BCS-BEC crossover

Authors: W. Wen, G. Huang

Journal: Physical Review A

Year: 2009

Citations: 42

📝Interference patterns of superfluid Fermi gases in the BCS-BEC crossover released from optical lattices

Authors: W. Wen, Y. Zhou, G. Huang

Journal: Physical Review A

Year: 2008

Citations: 38

📝Dark-soliton dynamics and snake instability in superfluid Fermi gases trapped by an anisotropic harmonic potential

Authors: W. Wen, C. Zhao, X. Ma

Journal: Physical Review A

Year: 2013

Citations: 29

📝Frequency shift and mode coupling of the collective modes of superfluid Fermi gases in the BCS-BEC crossover

Authors: Y. Zhou, W. Wen, G. Huang

Journal: Physical Review B

Year: 2008

Citations: 25

📝Collective modes of quasi-one-and quasi-two-dimensional superfluid Fermi gases in a BCS–BEC crossover

Authors: W. Wen, G. Huang

Journal: Physics Letters A

Year: 2007

Citations: 15

📝Collective dipole oscillations in a mixture of Bose and Fermi superfluids in the BCS–BEC crossover

Authors: W. Wen, H. Li

Journal: New Journal of Physics

Year: 2018

Citations: 8

Oluwafemi Omoniyi Oguntibeju – Phytomedicine – Best Researcher Award 

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Prof. Oluwafemi Omoniyi Oguntibeju began his academic journey in Nigeria, earning foundational qualifications in medical laboratory sciences. He became a qualified biomedical scientist in 1992 and completed his national youth service corps in 1993. He furthered his academic career with a POSTGRADUATE DIPLOMA (FIMLS) in Clinical Biochemistry in 1994 and obtained an MSc in Biochemistry from the University of Ibadan in 1997. His commitment to higher learning culminated in a PhD in Biomedical Science (Clinical Biochemistry) from the Central University of Technology, Free State, South Africa in 2005, establishing a strong academic platform for his future accomplishments, especially in Phytomedicine and biomedical science.

💼 Professional Endeavors

Prof. Oguntibeju’s professional trajectory spans several countries and continents. He served as a Senior Lecturer and Course Director at Spartan Health Sciences University, St. Lucia, and completed postdoctoral fellowships at the Central University of Technology and later at the Cape Peninsula University of Technology (CPUT), South Africa. Joining CPUT in 2009 as a Lecturer, he rose rapidly to Full Professor by 2014, owing to his prolific academic output and leadership. He currently serves as Group Leader of the Phytomedicine & Phytochemistry Group in the Department of Biomedical Sciences, engaging in groundbreaking research in Phytomedicine, HIV/AIDS, and diabetes mellitus.

🔬 Contributions and Research Focus

Prof. Oguntibeju’s RESEARCH FOCUS INCLUDES Phytomedicine, HIV/AIDS, diabetes mellitus, and natural products. He has made extensive contributions through over 250 peer-reviewed journal articles, 21 book chapters, and 6 books, some of which are key references in the biomedical sciences. His work in Phytomedicine has pioneered natural therapeutic approaches to chronic diseases, integrating traditional knowledge with modern science. He has supervised more than 65 postgraduate students, including 16 PhDs and 24 master’s candidates, and mentored five postdoctoral research fellows, showcasing his dedication to academic mentorship and development.

🌍 Impact and Influence

Prof. Oguntibeju's influence extends globally. He has presented over 70 papers at national and international conferences and serves on editorial boards of numerous scientific journals. His contributions have earned him widespread acclaim, including the Gold and Platinum Research Excellence Awards, the Award for Excellence in Biomedical Research (2015), and the distinction of being an NRF C-rated researcher. Additionally, he holds fellowships from prestigious institutions including the Royal Society of Chemistry (UK), the American College of Nutrition, and the Australasian College of Biomedical Scientists, positioning him as a thought leader in biomedical and phytochemical sciences.

🏆Academic Cites

Prof. Oguntibeju’s scholarly work is widely cited, reflecting the relevance, depth, and innovation of his contributions, especially in areas like Phytomedicine, clinical biochemistry, and public health. His work forms a critical resource in medical science curricula and ongoing research, both within Africa and internationally. With over 250 journal articles, his research is a cornerstone for those exploring the intersection of natural products and chronic disease management.

🌟 Legacy and Future Contributions

Prof. Oguntibeju’s legacy is firmly rooted in scholarly excellence, impactful mentorship, and pioneering research. His future endeavors aim to advance the integration of Phytomedicine into mainstream healthcare through evidence-based studies and international collaborations. His current supervision of doctoral and master’s students, along with continuous research funding and institutional leadership, assures his ongoing contribution to global biomedical innovation. His vision includes not only advancing science but also empowering the next generation of African researchers and contributing to global health through natural therapeutic discoveries.

📝Phytomedicine

Prof. Oguntibeju's scientific achievements are deeply rooted in Phytomedicine, where he continues to bridge traditional healing and modern biomedical science. His innovative research in Phytomedicine has advanced natural therapeutic approaches to chronic diseases. With an enduring commitment to Phytomedicine, he is shaping the future of biomedical science through natural product research and integrative healthcare solutions.

Notable Publication

📝Epigallocatechin-3-gallate mitigates diazinon neurotoxicity via suppression of pro-inflammatory genes and upregulation of antioxidant pathways

Authors: Charles Etang Onukak, Omowumi Moromoke Femi-Akinlosotu, Adedunsola Adewunmi Obasa, Oluwafemi Omoniyi Oguntibeju, MA Audu Yakubu

Journal: BMC Neuroscience

Year: 2025

Article Type: Open access, Journal article

📝Phenolic compounds profile and hypoglycaemic, anti-inflammatory and antioxidant properties of aqueous leaf extract of Androstachys johnsonii Prain: In vitro study

Authors: Murendeni Nethengwe, Nasifu Kerebba, Kunle Okaiyeto, Chinyerum Sylvia Opuwari, Oluwafemi Omoniyi Oguntibeju

Journal: South African Journal of Botany

Year: 2025

Article Type: Open access, Journal article

📝The effect of Garcinia livingstonei aqueous leaf extract on hyperglycaemic-induced human sperm cell: An in-vitro study

Authors: Murendeni Nethengwe, Kunle Okaiyeto, Chinyerum Sylvia Opuwari, Oluwafemi Omoniyi Oguntibeju

Journal: Phytomedicine Plus

Year: 2025

Article Type: Open access, Journal article

📝Antidiabetic, anti-inflammatory, antioxidant, and cytotoxicity potentials of green-synthesized zinc oxide nanoparticles using the aqueous extract of Helichrysum cymosum

Authors: Achasih Quinta Nkemzi, Kunle Okaiyeto, Omolola Rebecca Oyenihi, O. E. Ekpo, Oluwafemi Omoniyi Oguntibeju

Journal: 3 Biotech

Year: 2024

Article Type: Open access, Journal article

📝Flavonoid-rich fraction of Monodora tenuifolia Benth seeds improves antioxidant status in male Wistar rats with streptozotocin-induced Diabetes mellitus

Authors: Samuel Chibueze Nzekwe, Adetoun Elizabeth Morakinyo, Monde Mc Millan Ntwasa, Oluboade Oluokun Oyedapo, Ademola Olabode Ayeleso

Journal: Phytomedicine Plus

Year: 2024

Article Type: Open access, Journal article

📝In vitro hypoglycemic, antioxidant, anti-inflammatory activities and phytochemical profiling of aqueous and ethanol extracts of Helichrysum cymosum

Authors: Achasih Quinta Nkemzi, Kunle Okaiyeto, Nasifu Kerebba, O. E. Ekpo, Oluwafemi Omoniyi Oguntibeju

Journal: Phytomedicine Plus

Year: 2024

Article Type: Open access, Journal article

Ravi Bathe – Ultrafast Laser Interaction – Best Researcher Award 

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Dr. Ravi Bathe's academic journey began with a solid foundation in Physics, earning his B.Sc. in Physics from Pune University in 1993 with First Class with Distinction. He continued his education with an M.Sc. in Physics from Pune University in 1995, also securing First Class. His deep interest in condensed matter physics led him to pursue a Ph.D. in Physics at Pune University, completing his doctoral work in 2000. His Ph.D. thesis, titled "Influence of Dopants and Defects on the Properties of Colossal Magnetoresistance Manganite Systems," focused on advanced material properties, laying the groundwork for his future research endeavors.

💼 Professional Endeavors

Dr. Bathe's professional career has been marked by significant roles in renowned institutions, beginning with his current position as a Scientist at ARCI, Hyderabad, which he has held since 2003. He has also had prestigious international experience, including serving as a Visiting Scientist (IUSSTF Fellow) at Harvard University, Cambridge, USA, from 2009 to 2010. Earlier, Dr. Bathe worked as a Young Scientist (Fast Track Fellow) at the University of Pune (2002-2003) and as a Postdoctoral Research Fellow at the University of Maryland, College Park, USA (2000-2002). His career has been defined by his contributions to research in ultrafast laser interaction and material sciences, particularly in condensed matter and nanophysics.

🔬 Contributions and Research Focus

Dr. Bathe's research primarily focuses on the interaction of ultrafast lasers with materials, a field that has substantial applications in both basic science and technology. His research has significantly advanced the understanding of ultrafast laser dynamics, material properties, and their interaction with complex systems, particularly in relation to colossal magnetoresistance manganite systems. His work in ultrafast laser interaction is pivotal in developing new materials with tailored properties, advancing technologies such as ultrafast optical switches and high-precision measurement tools.

🌍 Impact and Influence

Dr. Bathe's work in the field of ultrafast laser interaction has had a profound impact on both the academic and technological communities. His research has opened new avenues for understanding the behavior of materials under high-intensity laser fields, influencing multiple subfields in physics and materials science. As a result of his expertise, Dr. Bathe has become a sought-after researcher and speaker at international conferences and has contributed to advancements in ultrafast optics, magnetoresistive materials, and laser-material interactions. His influence also extends through his roles in prestigious research fellowships and collaborations, including at Harvard University and the University of Maryland.

🏆Academic Cites

Dr. Ravi Bathe’s research has earned significant recognition in the academic world, with numerous citations of his work on ultrafast laser interaction. His publications have become essential references for researchers in the fields of materials science, ultrafast optics, and condensed matter physics. The citations of his work demonstrate the relevance and importance of his contributions, which continue to shape future research in ultrafast laser dynamics and material characterization.

🌟 Legacy and Future Contributions

Looking to the future, Dr. Bathe is committed to further advancing research in ultrafast laser interaction, particularly exploring new materials and techniques to manipulate laser-material interactions at even finer timescales. His ongoing work promises to lead to the development of advanced technologies in ultrafast optics, laser spectroscopy, and material design. As a mentor and researcher, Dr. Bathe’s legacy will undoubtedly influence future generations of scientists, particularly those working on cutting-edge material science and ultrafast laser technologies.

📝Ultrafast Laser Interaction

Dr. Ravi Bathe's extensive research into ultrafast laser interaction has provided critical insights into how materials respond to intense, high-speed laser pulses. His work in ultrafast laser interaction has paved the way for new experimental techniques and technologies, especially in condensed matter and nanophysics. His groundbreaking contributions to ultrafast laser interaction continue to have a significant impact on both theoretical studies and practical applications in the development of advanced materials and laser technologies.

Notable Publication

📝Transition-element doping effects in La₀.₇Ca₀.₃MnO₃

Authors: K Ghosh, SB Ogale, R Ramesh, RL Greene, T Venkatesan, KM Gapchup, ...

Journal: Physical Review B

Year: 1999

Citations: 361

📝Electrical, thermal, and microstructural characteristics of Ti/Al/Ti/Au multilayer Ohmic contacts to n-type GaN

Authors: A Motayed, R Bathe, MC Wood, OS Diouf, RD Vispute, SN Mohammad

Journal: Journal of Applied Physics

Year: 2003

Citations: 230

📝Transport properties, magnetic ordering, and hyperfine interactions in Fe-doped La₀.₇₅Ca₀.₂₅MnO₃: Localization-delocalization transition

Authors: SB Ogale, R Shreekala, R Bathe, SK Date, SI Patil, B Hannoyer, F Petit, ...

Journal: Physical Review B

Year: 1998

Citations: 213

📝Laser surface texturing of gray cast iron for improving tribological behavior

Authors: R Bathe, V Sai Krishna, SK Nikumb, G Padmanabham

Journal: Applied Physics A

Year: 2014

Citations: 107

📝Multi-objective optimisation of pulsed Nd:YAG laser cutting process using integrated ANN–NSGAII model

Authors: S Chaki, RN Bathe, S Ghosal, G Padmanabham

Journal: Journal of Intelligent Manufacturing

Year: 2018

Citations: 88

📝Fluxless arc weld-brazing of aluminium alloy to steel

Authors: KP Yagati, RN Bathe, KV Rajulapati, KBS Rao, G Padmanabham

Journal: Journal of Materials Processing Technology

Year: 2014

Citations: 77

📝Evaluation of manganite films on silicon for uncooled bolometric applications

Authors: RJ Choudhary, AS Ogale, SR Shinde, S Hullavarad, SB Ogale, ...

Journal: Applied Physics Letters

Year: 2004

Citations: 71

Francis Rolphe Zemtchou – Energy Harvesting – Excellence in Research 

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Mr. Francis Rolphe Zemtchou began his academic journey in physics at the University of Dschang, Cameroon, where he earned his Bachelor of Science (B.Sc.) degree in 2017. His dedication to the field continued as he pursued a Master of Science (M.Sc.) degree in Physics from 2017 to 2019, focusing on the dynamics and vibration control of cantilever beams subjected to external flow. Currently, he is pursuing a PhD in Physics (2019–current) at the University of Dschang, Cameroon, with a project titled "Contribution to the Dynamic Study of Cantilever Sensors: Synchronization of Systems and Energy Harvesting."

💼 Professional Endeavors

As part of his professional endeavors, Mr. Zemtchou has worked extensively in research and teaching. His PhD research involves investigating energy harvesting from mechanical oscillators (such as pendulums, beams, and coupled systems) using piezoelectric and electromagnetic transduction principles. He is also conducting research on the synchronization of mechanical oscillators, such as Huygens pendulums and coupled inverted pendulums, contributing to the development of systems that can harness energy from vibratory motions. Additionally, his work on cantilever beam vibrations and their control through feedback laws contributes to the field of mechanical vibrations.

🔬 Contributions and Research Focus

Mr. Zemtchou’s primary research focus is on energy harvesting, specifically from vibratory energy in mechanical oscillators. His work investigates the potential of mechanical oscillators (such as pendulums and beams) to generate electrical energy via piezoelectric and electromagnetic transducers. He is also exploring the synchronization of mechanical oscillators, particularly in coupled systems, and how these systems can be optimized for energy harvesting. His contributions to the dynamics of cantilever sensors and the application of feedback laws in controlling vibrations have the potential to impact various practical engineering applications.

🌍 Impact and Influence

Mr. Zemtchou’s research has the potential to make a significant impact in the field of energy harvesting, particularly in the development of sustainable systems that can convert mechanical vibrations into electrical energy. By exploring new methods of synchronization in mechanical systems and improving the efficiency of vibratory energy harvesting, his work could influence both academic research and industrial applications. His focus on materials science, specifically the creep behavior of wood materials, further expands his contributions to a multidisciplinary approach to energy harvesting and mechanical systems.

🏆Academic Cites

Though his research is still in progress, Mr. Zemtchou's work in energy harvesting is beginning to gain attention in the academic community. His studies on the synchronization of oscillators and the use of piezoelectric and electromagnetic transduction principles have been referenced by peers in the field. As he continues to publish his findings, his contributions are likely to increase in visibility and academic citation.

🌟 Legacy and Future Contributions

Looking ahead, Mr. Zemtchou's future contributions are poised to continue pushing the boundaries of energy harvesting technology. His ongoing research into synchronization and vibratory energy conversion has the potential to significantly influence the development of energy-efficient systems in mechanical engineering. As he completes his PhD and engages with the broader academic and industrial communities, his legacy will be built upon further advancements in energy harvesting techniques, which could lead to more sustainable and efficient energy solutions.

📝Energy Harvesting

Mr. Zemtchou’s research in energy harvesting is focused on the development of systems that can efficiently convert mechanical vibrations into usable energy. Through his exploration of the synchronization of oscillators and his work with piezoelectric and electromagnetic transduction, he is making significant contributions to the field of energy harvesting. As his research continues, it is expected to play a major role in advancing energy harvesting technologies and their application in various engineering disciplines.

Notable Publication

📝Piezoelectric energy harvesting from beam vibrations induced by an aerodynamic force generated by a fluctuating wind

Authors: F.R. Zemtchou, Francis Rolphe; J.S. Mabekou Takam, Jeanne Sandrine; P.H. Louodop Fotso, Patrick Hervé; P.K. Talla, Pierre Kisito

Journal: Chaos, Solitons and Fractals

Year: 2025

Lili Zhao – Dielectrics – Best Researcher Award 

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Professor Lili Zhao’s academic journey began with a strong foundation in materials science and electrical engineering. From her early academic pursuits, she demonstrated an aptitude for innovation in functional materials, focusing especially on dielectrics and energy storage systems. Through rigorous academic training and research engagements, she cultivated a deep interest in polymer-based composites and ceramic filler designs, which later became the cornerstone of her scholarly contributions.

💼 Professional Endeavors

Prof. Zhao has established herself as a pioneering figure in the domain of dielectrics and energy storage materials. Currently leading research initiatives at the frontier of flexible capacitor technology, her professional endeavors are focused on engineering advanced dielectric materials with high energy density and mechanical flexibility. Her expertise spans composite film synthesis, interface engineering, and structural innovation, as seen in her introduction of the egg-like ceramic filler Ba₀.₃₄Sr₀.₅₁Ca₀.₁₅Zr₀.₁Ti₀.₉O₃-Y@Ba₀.₃₄Sr₀.₅₁Ca₀.₁₅Zr₀.₁Ti₀.₉O₃-Mn@ZrO₂ (BSCZT-Y@BSCZT-Mn@ZrO₂). Her work not only contributes to academic knowledge but also addresses practical challenges in miniaturizing flexible electronic devices.

🔬 Contributions and Research Focus

Prof. Zhao’s contributions are groundbreaking, particularly in designing high-performance flexible dielectrics. Her latest research introduces a novel multilayered ceramic filler architecture, mimicking an “egg effect,” to significantly enhance effective polarization (ΔP) and discharged energy storage density in PVDF-based composites. By leveraging the synergy between donor-rich cores, acceptor-rich shells, and wide bandgap oxide “eggshells,” she achieved an ultrahigh discharged energy density of 33.2 J/cm³, a ΔP of 28.5 μC/cm², and exceptional bending endurance. Her research focus lies in reducing leakage currents through deep electron traps and promoting α-to-β phase transitions in PVDF, all contributing to superior dielectric performance.

🌍 Impact and Influence

The impact of Prof. Zhao's work in dielectrics has been widely recognized within the global materials science and electronics communities. Her novel ceramic filler strategy sets new standards for the development of flexible capacitors, paving the way for low-power wearable and flexible electronic devices. The demonstrated ability of her composite films to retain over 92% capacitance after 600 full bends signifies a remarkable advancement in both durability and performance. Her interdisciplinary influence spans electronic engineering, materials chemistry, and applied physics.

🏆Academic Cites

Prof. Lili Zhao’s publications have attracted significant academic attention, being cited extensively in journals related to materials science, electronics, and dielectrics. Her development of deep electron traps and core-shell doping mechanisms in dielectric composites has become a reference point for ongoing research in flexible energy storage. The high citation frequency underscores the academic value and technical originality of her work, particularly in the context of improving energy density without compromising mechanical flexibility.

🌟 Legacy and Future Contributions

Prof. Zhao’s legacy is being shaped by her strategic vision and technical ingenuity in the realm of flexible dielectrics. Looking forward, she is poised to expand her research to multifunctional composites, smart sensors, and scalable capacitor devices. Her future contributions will likely integrate artificial intelligence-driven design and green materials, reinforcing her leadership in advancing sustainable, high-performance electronic components. Her continued mentorship and collaborations will nurture the next generation of researchers in dielectric materials science.

📝Dielectrics

Prof. Lili Zhao’s pioneering work in dielectrics has redefined the potential of ceramic-polymer composites for flexible electronics. Her breakthrough in multilayer ceramic filler design has positioned dielectrics at the forefront of high-performance capacitor research. By combining innovation, endurance, and scalability, she continues to set benchmarks in the field of dielectrics, enabling a future of smarter, smaller, and more flexible electronic devices.

Notable Publication

📝Natural Mechanical Energy-Induced Porous PANI/(Ba₀.₈₅Ca₀.₁₅)(Zr₀.₁Ti₀.₉)O₃/PVDF Excellent Piezoelectric-Catalyzed Degradation of Dyes

Authors: Caiming Wang, Yue Jia, Huiyan Zhou, Han Zhang, Lili Zhao

Journal: Chemical Engineering Journal

Year: 2025

📝Nonequilibrium Surface Oxygen Vacancy in MgTiO₃ Inducing Fast Optical Transformation Under Laser Irradiation

Authors: Yuang Chen, Yang Zou, Lili Zhao, Zijian Lei, Lixin Song

Journal: Ceramics International

Year: 2025

📝Preparation of Two–Dimensional Gradient Fillers Reinforced Polymer Nanocomposites for High–Performance Energy Storage of Dielectric Capacitors

Authors: Yan Wang, Wenhui Zhao, Lili Zhao, Dengwei Hu, Bin Cui

Journal: Journal of Energy Storage

Year: 2024

📝Ricci Curvature of Strongly Convex Kähler-Finsler Metrics

Authors: Bin Chen, Siwei Liu, Lili Zhao

Journal: Scientia Sinica Mathematica

Year: 2024

📝ZEROECG: Zero-Sensation ECG Monitoring by Exploring RFID MOSFET

Authors: Wenli Jiao, Ju Wang, Xinzhuo Gao, Dingyi Fang, Xiaojiang Chen

Publication Type: Conference Paper

Year: Not specified (presumed 2024 or 2025)

📝Improved Energy Storage Density of Sr₀.₇Bi₀.₂TiO₃-Based Relaxor Ferroelectric Ceramics via a Core-Shell-Structural Optimization Strategy

Authors: Ruicong Chen, Yan Wang, Wenhui Zhao, Lili Zhao, Bin Cui

Journal: Journal of Materials Science: Materials in Electronics

Year: 2024

Chamil Arkhasa Nikko Mazlan – Social Sciences – Best Researcher Award 

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Dr. Chamil Arkhasa Nikko Mazlan embarked on his academic path with a passion for music and education, completing a Bachelor’s Degree in Music (Performance) from the National Academy of Arts Culture and Heritage (ASWARA) between 2011 and 2014. His dedication to advancing music education led him to earn a Master’s Degree (2015–2016) and later a Doctor of Philosophy in Music Education (2019–2021), both from Universiti Pendidikan Sultan Idris (UPSI). These formative years laid the groundwork for a robust career centered on the fusion of music, pedagogy, and Social Sciences.

💼 Professional Endeavors

Dr. Chamil has carved out an impressive portfolio of professional accomplishments in academia, curriculum development, and international collaborations. He has served as a reviewer for multiple international journals, such as Musikolastika and Journal of ICT in Education, and has contributed to the formulation of national music curriculum frameworks for the Ministry of Education Malaysia. His role as a keynote speaker at high-profile conferences like ICOPE 2024 and Saraswati International Conference has further cemented his status as a thought leader in music education and Social Sciences. His appointments in various academic and curriculum committees reflect his influence across Malaysian educational policy and pedagogy.

🔬 Contributions and Research Focus

Dr. Chamil’s scholarly work and consultations are anchored in the interdisciplinary nexus of music education, digital innovation, and Social Sciences. His contributions include curriculum design for Malaysian Arts Schools, APEL-Q rubrics development, and interactive virtual reality-based music appreciation tools (Emarz). His research interests lie in merging technology with music pedagogy, promoting inclusive and innovative music education models through digital transformation in the arts. Through lectures, seminars, and committee work, he continues to bridge gaps between practice, theory, and policy.

🌍 Impact and Influence

Dr. Chamil’s impact resonates on both national and international stages. His leadership in shaping music education curricula has influenced generations of students and educators in Malaysia. As a member of strategic and ethics committees at UPSI, his guidance has helped ensure ethical, practical, and innovative approaches to education. His expertise in Social Sciences enables him to interpret educational trends through sociocultural lenses, thus crafting education policies that are inclusive, adaptive, and forward-thinking.

🏆Academic Cites

Dr. Chamil’s growing presence in scholarly circles is evidenced by his involvement in reputable journals and research platforms. His work on music education methodologies, digital learning tools, and Social Sciences-based music curriculum models has garnered attention from researchers across Southeast Asia and beyond. As both a cited author and academic reviewer, he contributes significantly to elevating scholarly standards and dissemination in his field.

🌟 Legacy and Future Contributions

Dr. Chamil Arkhasa Nikko Mazlan is poised to leave a lasting legacy as a pioneer in integrative music education rooted in Social Sciences and innovation. His future contributions are expected to continue reshaping how music is taught, assessed, and experienced in Malaysia and the wider region. With ongoing projects in curriculum development, international collaborations, and education technology, Dr. Chamil’s influence is bound to expand, making him a central figure in the evolution of music education.

📝Social Sciences

Throughout his career, Dr. Chamil has blended the principles of Social Sciences with artistic pedagogy, especially in curriculum innovation and educational research. His initiatives exemplify the integration of Social Sciences in analyzing and designing music learning systems. The future of music education, as envisioned by Dr. Chamil, places Social Sciences at its core—driving policy, pedagogy, and practice forward.

Notable Publication

🔍 Recent Research Highlights

📝Exploring the Integration of Bite-Sized Learning: A Scoping Review

  • Authors: CAN Mazlan et al.

  • Journal: Contemporary Educational Technology, Vol. 15(4), ep468

  • Year: 2023

  • Citations: 8

  • Focus: A comprehensive scoping review across disciplines, evaluating the implementation and effectiveness of microlearning (bite-sized learning) in education.

🎶 Music Education & Technology

📝E-learning Gamelan Ensemble Playing Techniques

  • Authors: CAN Mazlan, NAM Ramli, MH Abdullah, AI Uyub

  • Journal: Jurnal Seni Musik, Vol. 10(1), pp. 1–4

  • Year: 2021

  • Citations: 7

  • Focus: Digital instruction methods for traditional Gamelan music—highlighting cultural preservation through e-learning.

📝Utilizing Pragmatism in Jazz Guitar Reharmonization with Malay Asli Songs

  • Authors: CAN Mazlan, MH Abdullah

  • Journal: International Journal of Applied and Creative Arts (IJACA), Vol. 3(1), pp. 54–67

  • Year: 2020

  • Citations: 6

  • Focus: A pedagogical approach for learning jazz reharmonization using local Malay songs—integrating cultural music heritage with modern musical technique.

📝Perspective on Blended Learning for Instrumental Music

  • Authors: SF Arshad, MA Sulong, Z Hashim, CAN Mazlan

  • Journal: Journal of Positive School Psychology, Vol. 6(3), pp. 4936–4941

  • Year: 2022

  • Citations: 5

  • Focus: Evaluation of blended learning's effectiveness in teaching instrumental performance.

📝Design and Development of e-MARZ: VR for Music Education

  • Authors: AR Safian et al., incl. CAN Mazlan

  • Journal: Journal of Advanced Research in Applied Sciences and Engineering Technology

  • Year: 2024

  • Citations: 5

  • Focus: A practical, cost-effective VR solution for music education—bridging immersive tech with pedagogy.

🎼 Cultural and Musicological Contributions

📝Satu Tinjauan Muzikologi Lagu Melayu Asli

  • Authors: CAN Mazlan et al.

  • Journal: Jurai Sembah, Vol. 1(2), pp. 14–26

  • Year: 2020

  • Citations: 4

  • Focus: A musicological overview of traditional Malay Asli songs—analytical and preservation-driven.

📝Performing Arts in Cultural Tourism

  • Authors: CAN Mazlan et al.

  • Journal: International Journal of Religion, Vol. 5(10), pp. 1009–1018

  • Year: 2024

  • Citations: 3

  • Focus: How performing arts intersect with and enrich the cultural tourism landscape.

📝Guidebook on Jazz Guitar Harmony with Malay Asli Songs

  • Author: CAN Mazlan

  • Institution: Universiti Pendidikan Sultan Idris

  • Year: 2021

  • Citations: 3

  • Focus: Development and assessment of a teaching guide for jazz harmony using traditional Malay music as a framework.

Etido Inyang – Theoretical Physics – Excellence in Research 

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DR. ETIDO PATRICK INYANG began his scholarly journey with a strong foundational education in physics, graduating with a B.Sc. in Education Physics (Second Class Upper Division) from the University of Calabar in 2009. Demonstrating a continuous passion for scientific advancement, he pursued a Postgraduate Diploma in Physics (2014), an M.Sc. in Applied Nuclear Physics (2018), and earned a Ph.D. in Theoretical Nuclear Physics in 2021—all from the University of Calabar. His academic excellence was evident through consistently high GPAs and an unwavering commitment to the principles of Theoretical Physics.

💼 Professional Endeavors

In 2020, DR. INYANG joined the National Open University of Nigeria (NOUN) as a Lecturer II, quickly rising to Lecturer I by 2024. His responsibilities have included teaching core physics courses across various levels, such as Nuclear Physics, Mathematical Methods for Physics, and Elementary Particle Physics. Beyond teaching, he serves as the Examination Officer for the Department of Physics and a member of the Faculty of Science Ethics Committee, reflecting his leadership and dedication to academic integrity and student success. His consultancy work in radiation safety for Petrotech Oil Field Solutions highlights his applied expertise in Theoretical Physics and its practical applications.

🔬 Contributions and Research Focus

DR. INYANG’s research portfolio is richly diverse, yet deeply rooted in Theoretical Physics. His work focuses on quantum and mathematical physics, with key emphasis on Schrödinger equations, diatomic molecules, quantum information theory, atomic structure, and molecular processes in external fields. He has employed advanced mathematical techniques such as the Nikiforov-Uvarov Method, Extended NU Method, and Exact Quantization Rule to solve both relativistic and non-relativistic equations. Furthermore, his research in Applied Nuclear Physics explores the environmental distribution and effects of radioisotopes, while his work in Quantum Information Theory delves into entropy-based information analysis.

🌍 Impact and Influence

DR. INYANG is a leading voice in Nigerian and African physics research. With over 80 peer-reviewed publications, 65+ indexed in Scopus, and over 1,555 Google Scholar citations, he ranks among the top 500 researchers in Nigeria. His research has significantly influenced fields such as quantum thermodynamics, environmental radioactivity, and quantum computation, earning accolades such as the Best Researcher Award by Science Father and recognition as the fourth most-cited scholar at NOUN. His presence in local and international conferences continues to inspire fellow researchers and students alike.

🏆Academic Cites

With a consistently strong academic record and prolific publishing output, DR. INYANG’s works are widely referenced, contributing greatly to the scientific discourse in Theoretical Physics. His publications appear in prestigious journals, and he actively reviews for titles such as Molecular Physics, Physica Scripta, Indian Journal of Physics, and Nuclear Physics. As a Subject Editor for Communication in Physical Science, he ensures the dissemination of high-quality physics research.

🌟 Legacy and Future Contributions

DR. INYANG’s legacy lies in the fusion of rigorous theory with practical applications. His vision is to advance theoretical physics, quantum information, and environmental research through innovative methodologies, sustainability, and impactful technologies. Through TETFund and NOUN Senate research grants, he continues to pioneer projects on topics like radioactivity in agriculture, quantum heat engines, and Schrödinger solutions for molecular systems. As a 2023 Postdoctoral Fellow at Universiti Malaysia Perlis, he is poised to expand his global influence and further enrich Theoretical Physics research.

📝Theoretical Physics

Dr. Inyang’s expertise in Theoretical Physics allows him to tackle complex problems in quantum systems and nuclear modeling. His groundbreaking methods in Theoretical Physics have shaped emerging perspectives in both academia and industry. Through education, consultancy, and pioneering research, his dedication to Theoretical Physics continues to push the boundaries of modern science.

Notable Publication

📝Determination of Probability Density, Position and Momentum Uncertainties, and Information Theoretic Measures Using a Class of Inversely Quadratic Yukawa Potential

Authors: Etido P. Inyang, A. E. L. Aouami, Norshamsuri R. Ali, Norshah Rizal Ali, Syed Alwee Aljunid

Journal: Scientific Reports

Year: 2025

Citations: 0

📝Theoretical Models for the Thermodynamic Properties of Linear Triatomic Molecules

Authors: Edwin Samson Eyube, C. R. Makasson, Ekwevugbe Omugbe, A. M. Tahir, Clement Atachegbe Onate

Journal: Chemical Physics Letters

Year: 2025

Citations: 0

📝Vibrational Spectra for an Extended Cosine Hyperbolic Type Potential Model

Authors: Clement Atachegbe Onate, Ituen B. Okon, Edwin Samson Eyube, Abubakar D. Ahmed, Etido P. Inyang

Journal: Results in Chemistry

Year: 2025

Citations: 0

📝Analytical and Computational Study of Fisher and Shannon Information Entropies in One and Three-Dimensional Spaces for Exponential-Type Potential

Authors: Ituen B. Okon, Clement Atachegbe Onate, Eddy S. William, Abeer E. Aly, K. E. Essien

Journal: European Physical Journal Plus

Year: 2025

Citations: 0

📝Theoretical Computation of Eigenenergies, Expectation Values and Thermodynamic Functions of Shifted Deng-Fan-Hellmann Potential in External Fields

Authors: Eddy S. William, Samuel Okon Inyang, Ituen B. Okon, Clement Atachegbe Onate, Okpo O. Ekerenam

Journal: Computational and Theoretical Chemistry

Year: 2025

Citations: 1