Dieudonné NGA ONGODO | High energy physics | Best Researcher Award

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Assist. Prof. Dr. Dieudonné NGA ONGODO | High energy physics | Best Researcher Award

University of Yaoundé I | Cameroon

Dr. Dieudonné NGA ONGODO is a Cameroonian nuclear physicist and Senior Lecturer at the University of Yaoundé I, Faculty of Science, Department of Physics. With over a decade of professional and academic engagement, Dr. Nga Ongodo stands out as a prominent scholar, researcher, and educator, whose work spans nuclear instrumentation, quantum mechanics, and radiation protection. His contributions are firmly rooted in both fundamental physics and applied technologies, making him a vital figure in the African and international scientific communities.

👨‍🎓Profile

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🎓 Early Academic Pursuits

Dr. Nga Ongodo’s academic foundation was laid with a Baccalaureate in Mathematics and Physics from Lycée d’Obala (2004–2005). He then enrolled at the University of Yaoundé I, completing his Undergraduate studies in Physics (2005–2010), followed by a Master’s Degree in Physics (2011–2013), and later earning a PhD in Nuclear Physics in 2020. His academic trajectory reflects a strong grounding in core and advanced physics disciplines, preparing him for a research-intensive career.

🧑‍🏫 Professional Endeavors

Over more than a decade, Dr. Nga Ongodo has built a distinguished academic career. Since May 2023, he serves as a Senior Lecturer at the University of Yaoundé I, having previously worked as an Assistant Lecturer (2021–2023) and Part-time Teacher (2014–2021) in the same department. Beyond academia, he also lectures at Institut Universitaire la Vision and previously at Institut Universitaire Sup Prépa, further demonstrating his commitment to educational development. Additionally, he plays a pivotal role in public contract regulation as a recognized expert for both the Regulatory Agency of Public Contracts (ARMP) and the Ministry of Public Contracts.

🧪 Contributions and Research Focus

Dr. Nga Ongodo is a dynamic and innovative researcher whose work spans several cutting-edge domains in physics. His expertise includes nuclear instrumentation, FPGA systems, digital signal and pulse processing (DSP, DPP), and radiation dosimetry. He has also contributed to the use of artificial neural networks in analyzing mass spectra, and explores quantum mechanics and SU(3) symmetry through advanced mathematical models. By integrating fractional calculus, Bohr Hamiltonian formalism, and quark models, he provides deep insight into atomic nuclei and particle interactions. His research bridges theory and application, advancing nuclear physics both locally and globally.

🌍 Impact and Influence

Dr. Nga Ongodo’s scientific influence transcends national borders. He has participated in prominent international workshops and seminars, including the African School of Fundamental Physics (Rwanda, 2016) and IAEA-AFRA training sessions across Cameroon and Ethiopia. His groundbreaking publications are featured in top-tier journals such as the European Physical Journal, Modern Physics Letters, and the International Journal of Modern Physics, attesting to the global relevance and visibility of his work.

📈 Academic Citations

With 13 peer-reviewed articles published between 2019 and 2025, Dr. Nga Ongodo’s work has received increasing academic attention. He has co-authored papers on topics including heavy pentaquark masses, Bohr Hamiltonian models, and charmonium resonances using both classical physics and AI techniques. His collaborations with other leading African physicists highlight his role as a central figure in nuclear modeling and quantum structure analysis.

🛠️ Research Skills

Dr. Nga Ongodo’s research expertise is deeply rooted in a diverse and robust technical skill set that empowers both his investigative pursuits and pedagogical approach. He possesses advanced mastery in nuclear and numerical electronics, as well as specialized experience in detector electronics and FPGA (Field Programmable Gate Array) systems, which are vital for real-time data acquisition and signal processing in nuclear experiments. His strong foundation in mathematical modeling, particularly through sophisticated frameworks such as the Nikiforov–Uvarov and Heun methods, allows him to derive analytical solutions for complex quantum systems.

👨‍🏫 Teaching Experience

A passionate and student-centered educator, Dr. Nga Ongodo has taught an extensive range of subjects including Quantum Physics, Electromagnetism, Fluid Mechanics, Thermodynamics, and Radiation Protection. He is well-versed in both theoretical instruction and practical laboratory supervision. His active engagement in pedagogical development seminars, such as the 2022 Competency-Based Teaching Workshop, showcases his dedication to educational innovation and student success.

🏅 Awards and Honors

While formal awards are not explicitly listed, Dr. Nga Ongodo’s appointments and invited participation in elite research events, including those organized by C.E.T.I.C and the IAEA, serve as implicit recognition of his expertise and leadership. His invitation to speak at the 2025 Radiological Protection Workshop in Cameroon underscores his role as a national thought leader in nuclear safety and public health.

🚀 Legacy and Future Contributions

Looking ahead, Dr. Nga Ongodo is set to play an even more significant role in African scientific development, particularly in areas of radiation protection, data-driven nuclear modeling, and sustainable electronics for physics research. His recent work involving Artificial Neural Networks, topological quantum mechanics, and quantum gravity analogues points to a future of interdisciplinary research that bridges AI, quantum systems, and high-energy physics. His legacy will not only be defined by the depth of his research, but also by his transformational impact on Cameroon’s scientific infrastructure, his mentorship of emerging scholars, and his efforts to elevate African research onto the global stage.

Publications Top Notes

Effect of spin-spin interaction and fractional order on heavy pentaquark masses under topological defect space-times

  • Authors: D. Nga Ongodo, A. A. Atangana Likéné, J. M. Ema’a Ema’a, P. Ele Abiama, G. H. Ben-Bolie
    Journal: The European Physical Journal C
    Year: 2025

Hyperbolic tangent form of sextic potential in Bohr Hamiltonian: Analytical approach via extended Nikiforov–Uvarov and Heun equations

  • Authors: D. Nga Ongodo, A. Atangana Likéné, A. Zarma, J. M. Ema’a Ema’a, P. Ele Abiama, G. H. Ben-Bolie
    Journal: International Journal of Modern Physics E
    Year: 2025

Electric quadrupole transitions of triaxial nuclei via the Bohr Hamiltonian within the screened Kratzer–Hellmann potential

  • Authors: D. Nga Ongodo, A. A. Atangana Likéné, A. Zarma, S. Haman Adama, J. M. Ema’a Ema’a, G. H. Ben-Bolie
    Journal: The European Physical Journal Plus
    Year: 2025

Non-compact extra dimensions and flavor dependence of cc̄ and bb̄ mesons masses in a hot QCD medium with lattice, LO and NLO parametrizations of the Debye mass

  • Authors: A. A. Atangana Likéné, L. B. Ungem, D. C. Mbah, D. Nga Ongodo, R. Houzibe, F. B. Djeuyi Ndafeun
    Journal: Modern Physics Letters A
    Year: 2025

Quantum chromodynamics Lagrangian density and SU(3) gauge symmetry: A fractional approach

  • Authors: A. A. Atangana Likéné, D. Nga Ongodo, P. Mah Tsila, A. Atangana, G. H. Ben-Bolie
    Journal: Modern Physics Letters A
    Year: 2024

Hanyang Li | High energy physics | Best Researcher Award

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Prof. Hanyang Li | High energy physics | Best Researcher Award

Lab Director at Harbin Engineering University | China

Dr. Hanyang Li is a dedicated researcher and professor specializing in optical microcavity and laser propulsion technologies. With a background rooted in chemical engineering and physical chemistry, his journey spans top academic institutions and international collaborations. Currently a Professor at the College of Physics and Optoelectronic Engineering, Harbin Engineering University, Dr. Li integrates scientific innovation with practical applications, mentoring the next generation of photonics researchers and contributing extensively to high-impact journals.

👨‍🎓Profile

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📘 Early Academic Pursuits

Dr. Li’s academic foundation was laid at Heilongjiang University, where he earned a B.S. in Applied Chemistry (2003–2007). He then pursued a M.Eng. in Physical Chemistry (2007–2009) followed by a Ph.D. in Chemical Engineering and Technology (2009–2015) at the prestigious Harbin Institute of Technology. These formative years shaped his deep interest in optical systems, nanostructures, and laser-matter interactions, driving him toward cutting-edge interdisciplinary research.

💼 Professional Endeavors

Dr. Li has demonstrated exceptional academic progression, beginning as a Lecturer in the College of Science at Harbin Engineering University (2017–2021), rising to Associate Professor (2021–2024), and ultimately Professor in 2024. His global outlook is reflected in his role as a Visiting Research Fellow at the University of North Carolina at Charlotte (USA) from 2019–2020. These roles have not only enriched his teaching and research but also expanded his international collaborations.

🔬 Contributions and Research Focus

Dr. Li’s research revolves around fiber sensors, microresonators, whispering-gallery modes (WGM), and nano/microlaser systems. He has led groundbreaking projects funded by the National Natural Science Foundation of China, the Heilongjiang Provincial Foundation, and the China Postdoctoral Science Foundation. His work in co-doped nanofiber lasers, enzyme reaction monitoring in microcavities, and micropropulsion dynamics continues to push the boundaries of photonic innovation.

🌍 Impact and Influence

With over 110 SCI-indexed publications, including more than 50 as first/corresponding author, Dr. Li has significantly influenced the fields of microcavity optics and laser-based sensing systems. His H-index of 21 attests to the scholarly impact of his work. Two of his papers have earned cover-page recognition in ACS Photonics and Liquid Crystals, underscoring their novelty and scientific relevance. He also serves as a technical consultant to Harbin Kaimeisi Technology Co., Ltd., bridging academic research with industrial development.

📊 Academic Citations

Dr. Li’s research is widely cited in international journals, particularly in optics, nanomaterials, and sensor technologies. His works in Optics Letters, ACS Photonics, Applied Physics Letters, and Journal of Materials Chemistry C are frequently referenced, reflecting his status as a thought leader in integrated photonic systems and functional microdevices.

🧪 Research Skills

Dr. Li’s research arsenal includes optical design, microresonator fabrication, laser pulse diagnostics, and nanomaterial synthesis. He is adept in developing fiber-optic devices, performing real-time sensing, and constructing phase-change materials-based systems. His strength lies in multidisciplinary integration, combining chemistry, physics, and engineering to address fundamental and applied challenges.

📚 Teaching Experience

Since 2021, Dr. Li has taught “Microcavity Photonics Devices and Applications” at the graduate level and “Microcavity Optics” for undergraduates at Harbin Engineering University. These courses are crafted to empower students with both theoretical insight and experimental practice, preparing them to excel in modern photonics research.

🏅 Awards and Honors

Dr. Li’s academic excellence has been recognized through multiple research grants and fellowships, including support from the China Postdoctoral Science Foundation and the Natural Science Foundation of Heilongjiang Province. He is also an esteemed member of the Chinese Society for Optical Engineering, further attesting to his reputation in the scientific community.

🌟 Legacy and Future Contributions

Looking ahead, Dr. Li aims to deepen his work on optical microdevices and laser-driven micropropulsion, with plans to develop next-gen photonic systems for biomedical, aerospace, and energy applications. His commitment to scientific excellence, industry collaboration, and student mentorship positions him as a key figure in shaping the future of photonic technology in China and beyond.

Publications Top Notes

The experimental study on concentration disturbance pattern and conversion mechanism of underwater plasma laser propulsion

  • Authors: Y. Ge, X. Tang, Y. Chen, X. Yang, H. Li
    Journal: Optics and Lasers in Engineering
    Year: 2025

Fiber Bragg grating-based method for underwater object angular measurement

  • Authors: H. Li, Y. Song, J. Wang, X. Dou
    Journal: Measurement Science and Technology
    Year: 2025

Observation of microsphere clusters separated by pulsed laser in water environment

  • Authors: Y. Ge, G. Zhou, X. Yang, J. Sun, H. Li
    Journal: Laser Physics
    Year: 2025

Observation of spectral splitting of whispering-gallery modes in asymmetrical photonic molecules

  • Authors: J. Wang, J. Sun, Y. Zhang, Z.I. Liu, H. Li
    Journal: Optics Letters
    Year: 2024

Bragg grating-based all-optical continuous two-dimensional force perceptron

  • Authors: H. Li, Z. Wu, J. Dai, G. Zhou, J. Sun
    Journal: Measurement Science and Technology
    Year: 2024

Jerzy Dryzek | The matter particles | Excellence in Research Award

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Prof. Dr. Jerzy Dryzek | The matter particles | Excellence in Research Award

Professor at Institute of Nuclear Physics PAS | Poland

Prof. Jerzy Dryzek is a renowned physicist specializing in solid state physics and positron annihilation spectroscopy, with over four decades of academic and research experience. A pioneer in experimental physics in Poland, he has played a central role in developing advanced laboratory techniques in the field, particularly at the Institute of Nuclear Physics PAN in Kraków. His extensive international collaborations and leadership in scientific projects underscore his lasting influence in materials science and nuclear physics.

👨‍🎓Profile

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📚 Early Academic Pursuits

Dr. Dryzek embarked on his academic journey with a Master’s degree from the Academy of Mining and Metallurgy in Kraków (1975–1980), where he focused on the “Technology of thin films.” He simultaneously pursued another Master’s in Nuclear Physics from the Jagiellonian University in Kraków (1977–1981), conducting a thesis on the “Measurement of the positron lifetime in silver films.” His deep interest in positron-related phenomena led to his Ph.D. (1981–1986) in Solid State Physics, with a dissertation titled “Electrical conductivity and electrical properties of thin metallic films (Au, Ag, Cu).”

🧪 Professional Endeavors

Since 1987, Dr. Dryzek has held a permanent position at the Institute of Nuclear Physics in Kraków, where he has been instrumental in establishing and expanding the positron annihilation laboratory. His international exposure includes scientific visits to Münster University, Germany, Helsinki University of Technology, Finland, Texas Christian University, USA, and collaborative research at Chalmers University of Technology, Sweden, and KEK in Tsukuba, Japan. He also served as Professor at the University of Zielona Góra (2005–2009) and Opole University (2009–2014).

🔬 Contributions and Research Focus

Dr. Dryzek’s research focus lies in positron annihilation spectroscopy, with special emphasis on pulsed positron beams, two-dimensional Doppler broadening, and positron annihilation in flight. He has led multiple national and international research projects, exploring grain boundaries, resonance trapping, and nonhomogeneous systems. His innovative work includes the construction of Doppler broadening spectrometers and advancing methods of studying subsurface zones in metallic alloys.

🌍 Impact and Influence

Dr. Dryzek’s impact extends beyond laboratory research. Through his leadership in the Centre of Excellence ADREM, he contributes to applying physics to human health and environmental safety. His collaborative initiatives have fostered German-Polish scientific cooperation, and his lectures and research work have enriched institutions in Europe, the USA, and Japan. His influence is particularly notable in shaping positron annihilation research infrastructure in Poland.

📖 Academic Cites

Dr. Dryzek’s work has been widely cited in peer-reviewed journals and international conferences, especially in the context of tribology, surface studies, and positron annihilation in condensed matter. His habilitation thesis in 2001, titled “Positron annihilation characteristics in condensed matter,” laid the foundation for his recognition as an Assistant Professor and later Full Professor in 2012.

🛠️ Research Skills

Dr. Dryzek demonstrates expertise in experimental physics, with deep proficiency in positron annihilation techniques, Doppler spectroscopy, and positron beam construction. He is also skilled in research project management, having led numerous scientific grants, coordinated interdisciplinary networks such as POSMAT, and conducted technology-based studies on materials like polymers, metals, and minerals.

👨‍🏫 Teaching Experience

Alongside research, Dr. Dryzek has actively contributed to academic teaching, notably as a lecturer in physics at the Pedagogical University in Kraków (1990–1992) and as a visiting professor at international institutions. He played a significant role in educating students from Münster University, fostering cross-border scientific knowledge exchange under the German-Polish Collaboration framework.

🏆 Awards and Honors

Among his recognitions are several competitive research grants awarded by the Committee of Scientific Research in Poland, European Commission (COST Programs), and German-Polish Foundations. His leadership in teaching grants, instrument development, and joint international projects reflects the high regard of his contributions to science and education.

🔮 Legacy and Future Contributions

With a legacy rooted in scientific innovation, academic mentorship, and international collaboration, Dr. Dryzek has established himself as a pioneer in positron physics. His work continues to inspire future generations, and his efforts in network coordination, grant acquisition, and technical development ensure ongoing contributions to the fields of solid-state physics and material science. His vision for advancing positron annihilation studies remains a guiding light for both theoretical and applied physics communities.

Publications Top Notes

Superior barrier performance, mechanical properties and compostability in relation to supramolecular structure of renewable based poly(trimethylene furanoate) modified with suberic acid

  • Authors: A. Zubkiewicz, A. Szymczyk, J. Dryzek, V.M. Siracusa, N. Lotti
    Journal: European Polymer Journal
    Year: 2025

Positronium Formation on the Rhenium Surface Studied by Slow Positron Measurements

  • Authors: J. Dryzek, M.O. Liedke, M. Butterling, E. Dryzek
    Journal: Physica Status Solidi (B) Basic Research
    Year: 2025

Influence of flexible segment length on the phase structure and properties of poly(hexamethylene 2,5-furandicarboxylate)-block-biopolytetrahydrofuran copolymers

  • Authors: S. Paszkiewicz, K. Walkowiak, I. Irska, Z.J. Rozwadowski, J. Dryzek
    Journal: Journal of Applied Polymer Science
    Year: 2024

Positron Annihilation and EBSD Studies of Subsurface Zone Created During Friction in Vanadium

  • Authors: J. Dryzek, M.X. Wróbel
    Journal: Journal of Tribology
    Year: 2023

Influence of the positron implantation profile on the study of the defect depth distribution by the positron annihilation technique

  • Authors: J. Dryzek
    Journal: Journal of Applied Physics
    Year: 2023

 

 

Yueling Yang | High energy physics | Best Researcher Award

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Prof. Yueling Yang | High energy physics | Best Researcher Award

Professor at Henan Normal University | China

Yueling Yang is a Professor of Physics at Henan Normal University, specializing in theoretical particle physics. With extensive expertise in weak decays, quantum chromodynamics (QCD), and the phenomenology of B mesons, she has established herself as a prominent researcher in the field. Over the years, she has progressed from an Assistant Professor to a Professor, teaching and conducting research at one of China’s leading institutions in the realm of theoretical physics.

👨‍🎓Profile

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📚Early Academic Pursuits

Yueling Yang’s academic journey began at Yanbei Normal University, where she obtained her Bachelor of Science in Physics (2000). She pursued her Master of Science in Theoretical Physics and later earned her Ph.D. in Theoretical Physics from Henan Normal University in 2014. Her graduate education laid a solid foundation for her future research endeavors, shaping her interests in particle physics and QCD phenomena.

👩‍🏫Professional Endeavors

Yang’s professional career spans over two decades, with extensive experience at Henan Normal University since 2003. After serving as an Assistant Professor at Yuncheng University, she returned to Henan Normal University in 2006. Over time, she was promoted to Lecturer, then Associate Professor, and finally, Professor. She currently holds the position of Professor of Physics at the Institute of Particle and Nuclear Physics, making her a key figure in academic leadership and research excellence.

🔬Contributions and Research Focus

Yueling Yang’s research primarily focuses on theoretical particle physics, specifically the study of weak decays of B mesons and heavy-flavored mesons. She has contributed to the understanding of nonfactorizable corrections in weak decays and the application of QCD factorization methods to nonleptonic decays. Her contributions also extend to the phenomenology of particle decays, an area central to understanding the standard model and searching for new physics beyond it.

🌍Impact and Influence

Yueling Yang’s work has had a substantial impact on the field of theoretical physics. Her research not only advances fundamental theoretical concepts but also bridges the gap between theoretical predictions and experimental possibilities, helping lay the groundwork for potential future experimental investigations in particle physics. Her publications, including 61 refereed journal articles, demonstrate her ongoing contribution to the academic community, and her work is often cited by leading researchers in the field.

📚 Academic Cites

Yueling Yang’s research has been widely cited in academic journals such as Eur. Phys. J. C, Phys. Rev. D, and Chin. Phys. C, demonstrating the scholarly reach and relevance of his contributions. His recent work on QED corrections and factorization approaches continues to gain traction among peers in the theoretical physics community.

🧪 Research Skills

Prof. Yang excels in theoretical modeling, perturbative QCD, and computational analysis for particle physics processes. His methodical approach to applying QCD factorization and examining nonperturbative effects enables nuanced predictions of weak decay channels. These skills have been critical in acquiring competitive funding from agencies like the National Natural Science Foundation of China.

📖Teaching Experience

As a renowned educator, Yueling Yang has played a crucial role in shaping the academic development of many students. She has received multiple teaching awards, including the “Top 10 Distinguished Teachers” and the “Outstanding Teachers” awards from Henan Normal University. Her commitment to excellence in teaching is also reflected in her work as an Excellent Master’s Thesis Supervisor, an honor she will continue to hold into 2024.

🏅 Awards and Honors

Prof. Yang has received 6 major honorary titles, including:

  • 🏆 Excellent Master’s Thesis Supervisor of Henan Province (2024)

  • 🥈 Second Class Prize of the Henan Natural Science Award (2023)

  • 🌟 Outstanding Teacher and Example Lesson recognitions from Henan Normal University (2018, 2021)

  • 🎓 Top 10 Distinguished Teachers (2015)

These accolades reflect his all-around excellence in both education and research.

🧬 Legacy and Future Contributions

Looking ahead, Prof. Yueling Yang continues to expand his research on new physics effects in heavy meson decays and aims to bridge theory with upcoming experimental data from international particle collider facilities. His legacy is being shaped not only through his scientific contributions but also by the next generation of physicists he mentors. With new research grants and international collaborations underway, Prof. Yang is poised to make even deeper contributions to the understanding of fundamental particles and forces.

Publications Top Notes

The QED nonfactorizable correction to the semileptonic charmed three-body B decays

  • Authors: Yueling Yang, Liting Wang, Jiazhi Li, Qin Chang, Junfeng Sun
    Journal: European Physical Journal C
    Year: 2024

CEPC Technical Design Report: Accelerator

  • Authors: Waleed Abdallah, Tiago Carlos Adorno de Freitas, Konstantin G. Afanaciev, Tianlu Chen, Wei Chen
    Journal: Radiation Detection Technology and Methods
    Year: 2024

STCF conceptual design report (Volume 1): Physics & detector

  • Authors: M. N. Achasov, X. C. Ai, L. P. An, Baolin Hou, T. J. Hou
    Journal: Frontiers of Physics
    Year: 2024

Possibility of experimental study on nonleptonic weak decays

  • Authors: Yueling Yang, Liting Wang, Jinshu Huang, Qin Chang, Junfeng Sun
    Journal: Chinese Physics C
    Year: 2023

Feasibility of searching for the Cabibbo-favored D∗ → K ¯ π+, K ¯ ∗π+, K ¯ ρ+ decays

  • Authors: Yueling Yang, Kang Li, Zhenglin Li, Qin Chang, Junfeng Sun
    Journal: Physical Review D
    Year: 2022

 

Mohammed salah Abd El minem | High energy physics | Physics Excellence in Industry Award

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Dr. Mohammed salah Abd El minem | High energy physics | Physics Excellence in Industry Award

Assistant Professor at Physics Department, Faculty of Science, Al-Azhar University, Egypt

Mohamed Salah Abdel-Moneim Youssef is an Assistant Lecturer at the Department of Physics at Al-Azhar University, Assiut, Egypt. He holds a Bachelor’s degree in Physics (2012) and a Master’s degree from Al-Azhar University with a focus on optical properties of BiI3 thin films. He has been actively involved in teaching, research, and scientific activities, contributing significantly to the field of material science and optoelectronics.

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Early Academic Pursuits 🎓

Mohamed began his academic journey at Al-Azhar University, where he earned his Bachelor’s degree in Physics in 2012. His academic prowess and commitment to the field were recognized when he was appointed as a Demonstrator in the Department of Physics in 2018. This early appointment demonstrated his passion for physics and his readiness to contribute to the academic community.

Professional Endeavors 🏢

Since 2018, Mohamed has worked as an Assistant Lecturer at Al-Azhar University, where he teaches both undergraduate and preparatory dental students. His teaching responsibilities include specialized courses such as Solid-State Physics, Electronics, Semiconductors, Nuclear Physics, and Modern Physics. His teaching experience reflects his broad knowledge of physics and his ability to simplify complex concepts for diverse student groups.

Contributions and Research Focus 🔬

Mohamed’s primary research focuses on material science and optoelectronics, particularly the structural and optical properties of thin films. His Master’s thesis was centered around the impact of gamma-irradiation on BiI3 thin films, aiming to improve optoelectronic devices. Two notable publications emerged from this research, contributing to the understanding of optical parameters in photovoltaic and nonlinear applications.

His PhD research continued to explore materials science, specifically the substitution of BaTiO3 in lead borosilicate glass for ultrasonic applications, published in the Journal of Materials Science: Materials in Electronics.

Impact and Influence 🌍

Through his research and academic contributions, Mohamed has played a key role in advancing the study of materials for optoelectronic applications. His work on BiI3 thin films and BaTiO3-substituted borosilicate glass has the potential to impact industries related to photovoltaics, optoelectronics, and ultrasonic technologies. By focusing on improving material properties, his research has practical applications that can enhance the performance and efficiency of various technologies.

Academic Cites 📚

Mohamed’s research has garnered recognition in prominent scientific journals. His paper on BaTiO3 substitution in borosilicate glass was published in the Journal of Materials Science: Materials in Electronics (35 (22), 1534). Additionally, his Master’s research resulted in two significant papers that have been well-received in the field of optoelectronics. These publications contribute to the growing body of knowledge in the field of materials science and physics.

Research Skills 🔍

Mohamed is proficient in a variety of research methodologies, including material characterization techniques such as ball milling, gamma-irradiation, and thin film deposition. He has hands-on experience in structural and optical characterization of materials, specifically in the context of optoelectronic applications. His analytical skills and ability to synthesize complex data enable him to draw meaningful conclusions that enhance our understanding of material properties.

Teaching Experience 🎓

In addition to his research activities, Mohamed has been actively involved in teaching physics since 2018. He has taught a variety of courses, including both general physics and specialized courses in solid-state physics, semiconductors, and nuclear physics. His ability to communicate complex ideas clearly and his commitment to educating the next generation of scientists demonstrate his dedication to academic excellence.

Legacy and Future Contributions 🚀

Looking forward, Mohamed is poised to continue making significant contributions to materials science and optoelectronics. His ongoing research, particularly in optical and ultrasonic technologies, holds immense potential for future industrial applications. As he continues to expand his research, collaborate with other researchers, and enhance his teaching, Mohamed will likely leave a lasting impact on both the academic and industrial communities.

Publications Top Notes

Structural and optical investigations of multi-component lead-borosilicate glasses containing PbO, BaO, and TiO2

  • Authors: M. Salah, El Sayed Moustafa, A.A. Showahy
    Journal: Optical Materials
    Year: 2025

Influence of BaTiO3 substitution on structural and thermal response of lead borosilicate glass for ultrasonic applications

  • Authors: M. Salah, El Sayed Moustafa, A.A. Showahy
    Journal: Journal of Materials Science: Materials in Electronics
    Year: 2024

Influence of γ-irradiation dose on the structure, linear and nonlinear optical properties of BiI3 thick films for optoelectronics

  • Authors: AM Abdelnaeim, M Salah, E Massoud, A EL-Taher, ER Shaaban
    Journal: Digest Journal of Nanomaterials & Biostructures (DJNB)
    Year: 2022

Optical parameters of various thickness of bismuth (III) iodide thin films for photovoltaic and nonlinear applications

  • Authors: M Salah, A Abdelnaeim, S Makhlolf, A El-Taher, ER Shaaban
    Journal: International Journal of Thin Film Science & Technology
    Year: 2022

A new one-parameter lifetime distribution and its regression model with applications

  • Authors: MS Eliwa, E Altun, ZA Alhussain, EA Ahmed, MM Salah, HH Ahmed, …
    Journal: PLOS ONE
    Year: 2021

 

Vien Vo Van | High-Energy Physics | Best Researcher Award

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Assoc. Prof. Dr. Vien Vo Van | High-Energy Physics | Best Researcher Award

Lecturer at Tay Nguyen University | Vietnam

Dr. Vo Van Vien is a Senior Lecturer at Tay Nguyen University, specializing in Theoretical Physics with an emphasis on Neutrino Physics and Standard Model Extensions. He has an impressive academic background with a Bachelor’s degree from Vinh University, a Master’s from Ha Noi National University of Education, and a Doctorate from the Institute of Physics, Vietnam. His research primarily focuses on high-energy physics and particle phenomenology.

👨‍🎓Profile

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Early Academic Pursuits 📚

Dr. Vien’s academic journey began with a Bachelor’s degree in Theoretical Physics from Vinh University (1999-2003), followed by a Master’s degree in Theoretical Physics and Mathematical Physics from Ha Noi National University of Education (2006-2008). He then pursued a PhD at the Institute of Physics (2009-2014), where his research deepened his expertise in neutrino physics and discrete symmetry models.

Professional Endeavors 💼

Dr. Vien has been a Senior Lecturer at Tay Nguyen University since 2004, where he continues to teach and mentor the next generation of physicists. His academic position has allowed him to lead several high-impact research projects in particle physics, neutrino mass mixing, and flavor symmetries. Notably, he has been the Principal Investigator for multiple funded projects including studies on lepton and quark mixings in extended Standard Models.

Contributions and Research Focus 🔬

Dr. Vien’s research contributions have been pivotal in extending the Standard Model, especially in neutrino physics, particle mass mixing, and discrete symmetries. His projects have explored a range of models like B-L models, flavor symmetries (e.g., A4, S4, Z4), and the muon anomaly. He has also contributed significantly to understanding neutrino oscillation phenomenology and the implications for dark matter in various extended models.

Impact and Influence 🌍

Dr. Vien’s work has significantly impacted the field of particle physics and neutrino phenomenology. His research on neutrino mass, mixing, and symmetry breaking models has been widely cited and recognized in global academic circles. His collaborations with prominent researchers and his leadership in international research projects underscore his influence in advancing high-energy physics.

📑 Academic Cites

Through his cutting-edge research, Dr. Vien has garnered significant recognition within the scientific community. His publications and citations have had a noticeable impact on the development of high-energy physics and mathematical models used in modern particle physics. His research has been cited by peers, especially those exploring theoretical extensions of the Standard Model and the neutrino sector.

Research Skills 🛠️

Dr. Vien has exceptional skills in Theoretical Physics, particularly in neutrino phenomenology, standard model extensions, and discrete symmetries. His expertise in mathematical models is complemented by proficiency in high-energy particle simulations and advanced theoretical methods, ensuring his research is at the cutting edge of particle physics.

Teaching Experience 🧑‍🏫

As a Senior Lecturer at Tay Nguyen University, Dr. Vien has mentored and inspired numerous students in theoretical physics and mathematical physics. He is known for his innovative teaching methods, combining advanced theoretical concepts with practical examples to help students understand complex phenomena in high-energy physics. His dedication to education ensures that his students are well-prepared to pursue careers in both academia and industry.

Awards and Honors 🏅

Dr. Vien has received several awards and accolades for his academic excellence and research leadership, including:

  • National Foundation for Science and Technology Development grants for his research on Fermion mass and mixing.

  • Tay Nguyen University Principal Investigator awards for his work in extending the Standard Model and exploring new physics.

  • Recognition in peer-reviewed journals for his groundbreaking research in neutrino physics and dark matter.

Legacy and Future Contributions 🌠

Dr. Vo Van Vien’s legacy lies in his substantial contributions to particle physics and his dedication to educating future generations of physicists. His ongoing research promises to further unravel the complexities of neutrino physics, dark matter, and the Standard Model extensions. With a vision of pushing the boundaries of high-energy physics, Dr. Vien is poised to make lasting contributions to theoretical physics that could have a profound impact on how we understand the universe.

Publications Top Notes

Realistic fermion mass and mixing in U(1)L model with A4 flavor symmetry for Majorana neutrino

  • Authors: V.V. Vien, Vo Van
    Journal: Indian Journal of Physics
    Year: 2025

Lepton masses and mixings with broken μ−τ symmetry in a B – L extended 3HDM based on (Z2×Z4)⋊Z2 (I) symmetry

  • Authors: V.V. Vien, Vo Van
    Journal: Chinese Journal of Physics
    Year: 2025

The μ−τ reflection symmetry breaking in a B−L model with T7×Z8×Z2 symmetry

  • Authors: V.V. Vien, Vo Van
    Journal: Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics
    Year: 2024

A4×Z2×Z4 flavor symmetry model for neutrino oscillation phenomenology

  • Authors: V.V. Vien, Vo Van
    Journal: Revista Mexicana de Fisica
    Year: 2024

Fermion masses and mixings and g − 2 muon anomaly in a Q6 flavored 2HDM

  • Authors: V.V. Vien, Vo Van, H.N. Long, A.E. Cárcamo Hernández, J. Marchant González
    Journal: Nuclear Physics, Section B
    Year: 2024

 

 

 

Ngangkham Nimai Singh | High energy physics | Distinguished Scientist Award

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Prof. Dr. Ngangkham Nimai Singh | High energy physics | Distinguished Scientist Award

Professor at Manipur University | India

Dr. Ngangkham Nimai Singh is a distinguished Theoretical Physicist and the current Director of the Research Institute of Science and Technology (RIST) in Manipur. With an academic career spanning over 30 years, Dr. Singh has made remarkable contributions to High Energy Physics (HEP) and is an influential figure in scientific research and education. His expertise in Grand Unified Theories (GUTs), Neutrino Physics, and QCD-oriented hadronic models makes him a globally recognized scientist.

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Early Academic Pursuits 🎓

Dr. Singh’s educational journey began in Manipur, where he completed his early schooling before moving to Delhi University. There, he earned a B.Sc. in Physics (Hons.) in 1979, followed by an M.Sc. in Physics in 1981. His pursuit of higher knowledge led to an M.Phil. (1984) and a Ph.D. in Physics (1989), both from Delhi University, under the mentorship of the esteemed Prof. A. N. Mitra. Dr. Singh’s early academic training laid the foundation for his later contributions to theoretical physics.

Professional Endeavors 🌍

Dr. Singh’s professional career includes over 22 years of service at Gauhati University, where he held the positions of Lecturer, Reader, and eventually Professor. As Head of the Department of Physics (2010–2013), he played a crucial role in the department’s development. From 2013–2014, he served as a Professor and Head at Manipur University. Additionally, Dr. Singh has held various important positions such as Controller of Examination (I/C) at Manipur University and a PAC Member for International Cooperation/Physics at DST, New Delhi. His leadership extends to scientific bodies like PANE, NEAS, and MAPS.

Contributions and Research Focus 🔬

Dr. Singh’s research has had a transformational impact in the field of Theoretical High Energy Physics (HEP). His research interests include:

  • Grand Unified Theories (GUTs) such as SU(5) and SO(10), exploring the unification of the fundamental forces of nature.

  • Neutrino Physics, focusing on the origin of neutrino masses and mixings.

  • Baryogenesis through Leptogenesis, aiming to understand the matter-antimatter asymmetry in the universe.

  • Higgs Physics and Proton Decay, investigating the fundamental particles and forces.

  • Relativistic Few-Quark Dynamics and Quark Confinement, including QCD-oriented hadronic models and Bethe Salpeter Dynamics.

His research has contributed significantly to the understanding of the standard model of particle physics and beyond, particularly in the areas of neutrino masses, Higgs boson properties, and proton decay.

Impact and Influence 🌐

Dr. Singh’s impact extends far beyond his research. His role as a founding member of numerous scientific organizations, including the North East Academy of Sciences (NEAS), Physics Academy of North East (PANE), and Manipur Centre of Scientific Culture, highlights his dedication to the promotion of science in the northeastern region of India. Dr. Singh has also served as a visiting associate at prestigious institutions like PRL Ahmedabad and ICTP Trieste, fostering global collaborations. As President of PANE, he has worked tirelessly to advance scientific education and promote collaboration among physicists in the region, shaping the future of Physics in Northeast India.

Academic Cites 📚

Dr. Singh’s work has been cited in numerous academic papers and has contributed to the development of Grand Unified Theories (GUTs) and Neutrino Physics. His research on quark dynamics and light-cone physics has helped refine QCD models and deepen the scientific understanding of hadronic structures. His findings in Higgs physics, Baryogenesis, and Proton Decay continue to be foundational for researchers in particle physics worldwide.

Research Skills 🔍

Dr. Singh is highly skilled in theoretical modeling and quantitative analysis, focusing on complex phenomena in high-energy physics. His ability to formulate and solve problems in quantum chromodynamics (QCD), neutrino mass models, and baryogenesis is unmatched. Furthermore, his interdisciplinary approach, combining elements of quantum mechanics, relativistic dynamics, and cosmology, sets him apart as a pioneering researcher in his field.

Teaching Experience 🍎

With three decades of experience in academia, Dr. Singh has mentored and guided numerous graduate and postgraduate students. His role as a Professor and Head of the Department of Physics at Gauhati University and Manipur University allowed him to impart valuable knowledge on high-energy physics, theoretical models, and advanced quantum mechanics. He is also a respected research supervisor, helping students push the boundaries of particle physics.

Awards and Honors 🏅

Dr. Singh’s contributions have been widely recognized throughout his career:

  • Commonwealth Fellowship (1999-2000) at Southampton University, UK.

  • Visiting Associate at the Physical Research Laboratory (PRL), Ahmedabad.

  • Regular Associate at the ICTP, Trieste.

  • Member of the All India Theoretical Physics Seminar Circuit (2004-2005).

These accolades, along with his research collaborations and leadership in scientific societies, underscore his global recognition and influence in the scientific community.

Legacy and Future Contributions 🌱

Dr. Singh’s legacy is defined by his dedication to scientific progress and his mentorship of future generations of physicists. His involvement in founding scientific organizations in the Northeast has created lasting structures for the promotion of physics in the region. In the future, Dr. Singh’s research on neutrino physics, proton decay, and quark confinement is likely to continue influencing the field of high-energy physics. As a leader, educator, and researcher, he will undoubtedly leave an enduring mark on the scientific community, especially in advancing particle physics and cosmological theories.

Publications Top Notes

A5 symmetry and deviation from golden ratio mixing with charged lepton flavor violation

  • Authors: V. Puyam, Ngangkham Nimai Singh
    Journal: Nuclear Physics, Section B
    Year: 2025

Perturbation to μ -τ symmetry using type I and type II seesaw mechanisms under SU(2)L × Δ (27) × Z2 flavor symmetry

  • Authors: P. Wilina, Ngangkham Nimai Singh
    Journal: Modern Physics Letters A
    Year: 2025

Modular A4 symmetry in 3 + 1 active-sterile neutrino masses and mixings

  • Authors: Mayengbam Kishan Singh, Soram Robertson Singh, Ngangkham Nimai Singh
    Journal: International Journal of Modern Physics A
    Year: 2024

A randomly generated Majorana neutrino mass matrix using adaptive Monte Carlo method

  • Authors: Yuvraj Monitar Singh, Mayengbam Kishan Singh, Ngangkham Nimai Singh
    Journal: International Journal of Modern Physics A
    Year: 2024

Comparative analysis on the validity of golden ratio, tri-bimaximal, hexagonal and bimaximal neutrino mixing patterns under the radiative corrections

  • Authors: Yuvraj Monitar Singh, Moirangthem Shubhakanta Singh, Ngangkham Nimai Singh
    Journal: Physica Scripta
    Year: 2024

SHARJEEL AHMED | Particle Experiments | Best Researcher Award

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Dr. SHARJEEL AHMED | Particle Experiments | Best Researcher Award

PhD Researcher at University of Science and Technology China (USTC), Chinese Academy of Science,Institute of Metal Research (CAS, IMR) | China

Dr. Sharjeel Ahmed is a PhD Researcher at the University of Science and Technology China (USTC), Chinese Academy of Science, Institute of Metal Research (CAS, IMR), China. He completed his master’s degree from Donghua University (DHU), China, and earned his PhD from USTC. His research specializes in photoresponsive nanomaterials and smart fluorescence coatings, focusing on oxygen-deficient nanomaterials for photocolorswitching properties and early-stage corrosion detection.

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Early Academic Pursuits 🎓

Dr. Ahmed’s academic journey began at Donghua University (DHU), where he obtained his master’s degree. Building on this foundation, he continued his research at USTC, a leading institution in nanotechnology and materials science. His early academic work laid the groundwork for his specialization in nanomaterials and coating technologies that can respond to environmental triggers like light, opening new avenues in corrosion detection and smart materials.

Professional Endeavors 🏢

Throughout his professional career, Dr. Ahmed has collaborated with eminent scholars, such as Prof. Liu Fuchun from Northwestern Polytechnical University, and has contributed significantly to research projects focused on the preparation technology of micro-nano structures and self-repair mechanisms for coatings. His work bridges academic research and industry applications, ensuring his contributions are impactful both in laboratories and in practical solutions.

Contributions and Research Focus 🔬

Dr. Ahmed’s main research interests lie in photoresponsive nanomaterials, particularly in smart fluorescence coatings and early-stage corrosion detection. He has developed oxygen-deficient nanomaterials for photocolorswitching properties, which react to light stimuli to produce fluorescent signals when exposed to corrosive environments. These innovations have been pivotal in solving the limitations of traditional coatings, which lack intelligent early-warning systems.

He has authored 21 research articles in high-impact journals, including top publications like Chemical Engineering Journal, Nanoscale, and Colloids and Surfaces A. Additionally, he holds a patent (CN111394094-A; CN111394094-B) for a dual-band light-responsive reversible color solution, showcasing his innovative contributions to smart materials.

Impact and Influence 🌍

Dr. Ahmed’s research has had a substantial impact on materials science, especially in the development of smart coatings for corrosion detection. His fluorescent smart coatings are expected to revolutionize industries such as aerospace, automotive, and marine engineering, where early detection of corrosion can prevent extensive damage and improve material longevity. His work has been widely cited and continues to influence both academic research and practical applications in coatings technology.

Academic Cites 📚

With 422 citations and an h-index of 10, Dr. Ahmed has garnered recognition for his influential contributions to the field of nanomaterials and coatings technology. His papers, particularly as the first author, in journals such as Materials Chemistry and Physics and Journal of Materials Science and Technology, reflect the significant impact of his work within the scientific community.

Research Skills 🛠️

Dr. Ahmed has mastered several advanced techniques in nanomaterials preparation, including synthesis of oxygen-deficient materials, fluorescence analysis, and computational modeling. His research is not only grounded in experimental work but also utilizes computational science to predict the behavior of materials under various environmental conditions. His ability to combine both experimental and computational approaches gives his work a robust scientific foundation.

Teaching Experience 👨‍🏫

Though primarily a researcher, Dr. Ahmed’s teaching experience is an integral part of his professional journey. At USTC, he has contributed to educating the next generation of materials scientists, particularly in the area of nanomaterials and smart coatings. He mentors students and provides them with invaluable guidance on research methodology and cutting-edge technologies in nanotechnology.

Awards and Honors 🏅

Dr. Ahmed’s excellence in research has earned him recognition in the form of publications in top-tier journals and inclusion in major collaborative projects. Although specific awards are not listed, his patent and high citation index suggest that his work is highly respected within the scientific community. His ongoing research and contributions place him in a strong position to receive further academic and professional accolades.

Legacy and Future Contributions 🔮

Dr. Sharjeel Ahmed is paving the way for future innovations in smart materials, particularly in nanomaterials that are both responsive and intelligent. As his work continues to evolve, it will likely contribute to environmentally sustainable and cost-effective solutions for industries ranging from coatings and corrosion detection to advanced textiles. His future endeavors may include expanding his patent portfolio, collaborating with industries, and broadening his research into emerging areas such as energy storage materials or biodegradable coatings.

Publications Top Notes

  • A review of advancement in fluorescence-based corrosion detection for metals and future prospects
    Authors: Sharjeel Ahmed, Hongwei Shi, Mustehsin Ali, Imran Ali, Fuchun Liu, En-Hou Han
    Journal: Journal of Materials Science & Technology
    Year: 2025

  • Epoxy coating containing CoMOF@MBT metal-organic framework for active protection of aluminum alloy
    Authors: Nwokolo, Izuchukwu K.; Shi, Hongwei; Ikeuba, Alexander I.; Liu, Fuchun; Ahmed, Sharjeel; Zhang, Wanyu
    Journal: Surface and Coatings Technology
    Year: 2024

  • Modified Graphene Micropillar Array Superhydrophobic Coating with Strong Anti-Icing Properties and Corrosion Resistance
    Authors: Zhang, Wanyu; Liu, Fuchun; Li, Yushan; Chen, Tao; Nwokolo, Izuchukwu Kenneth; Ahmed, Sharjeel; Han, En-Hou
    Journal: Coatings
    Year: 2024

  • UV light-triggered fluorescence corrosion sensing coatings for AA2024-T3 based on 8-hydroxyquinline loaded vanadium oxide nanorods
    Authors: Sharjeel Ahmed
    Journal: Colloids and Surfaces A: Physicochemical and Engineering Aspects
    Year: 2024

  • Catalytic degradability and anti-permeability of peelable coating based on organophosphate nerve agent simulants
    Authors: Gao, Ningjie; Ahmed, Sharjeel; Zhang, Wanyu; Li, Jiwen; Liu, Fuchun
    Journal: Colloids and Surfaces A: Physicochemical and Engineering Aspects
    Year: 2023

 

Shewa Getachew | High energy physics | Editorial Board Member

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Mr. Shewa Getachew | High energy physics | Editorial Board Member

Lecturer at Wolkite University | Ethiopia

Shewa Getachew Mamo is a dedicated Physics Lecturer and researcher with a specialized focus on optical properties of nanocomposites, material science, refractive index, and group velocity. Passionate about advancing scientific knowledge, he is committed to both academic excellence and innovative research in the realm of condensed matter physics. His expertise extends to investigating local field enhancements, optical properties of nanostructures, and exploring nanoparticle-based materials and geometries.

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Early Academic Pursuits 🎓

Shewa’s academic journey began at Wolkite University, where he earned his Bachelor’s degree in Physics (2016-2019) and later pursued a Master’s degree in Condensed Matter Physics (2022-2023). Throughout his education, he developed a strong foundation in experimental and theoretical physics, which propelled him into a career of teaching and research in the field.

Professional Endeavors 💼

Currently, Shewa serves as a Physics Teacher at Wolkite University (since December 2023). In this role, he is responsible for preparing and presenting undergraduate and sometimes postgraduate courses in various areas of physics, including mechanics, electromagnetism, thermodynamics, quantum mechanics, and material science. He plays a vital role in designing curricula, developing lesson plans, and selecting relevant textbooks to ensure effective learning outcomes. His academic influence extends to advising students on academic matters and guiding them through research projects.

Contributions and Research Focus 🔬

Shewa’s research focus is primarily on the optical properties of core-shell spherical nanocomposites and local field enhancements. His research aims to explore the interaction between optical fields and nanocomposites, as well as investigating the influence of depolarization on the local field enhancement factor in passive and active composites with pure metal spheroidal nanoinclusions. One of his notable research areas includes optical bistability in nanoparticle composites and the role of tunable dielectric cores in cylindrical core-shell nanocomposites.

Impact and Influence 🌍

Shewa’s research has led to significant contributions to the field of material science and nanotechnology, specifically in understanding the optical properties of nanostructured materials. His findings have been widely discussed in the scientific community, with numerous publications in prominent journals. He is committed to staying updated with the latest advancements in condensed matter physics and nanotechnology, consistently striving to push the boundaries of existing scientific knowledge.

Academic Cites 📚

Shewa’s work has been widely cited, with his contributions being recognized across several prestigious journals. His publications include studies such as:

  • Tsegaye, A., & Getachew, S. (2024). “Investigation Optical Properties of ZnTe@Ag Core-Shell Spherical Nanocomposites Within Varies Dielectric Host Matrices”. Advances in Materials, 13(4), 80-91.
  • Getachew, S. (2024). “Effect of Tunable Dielectric Core on Optical Bistability in Cylindrical Core-Shell Nanocomposites”. Advances in Condensed Matter Physics, 2024(1), 9911970.
  • Getachew, S. (2024). “Investigation of Refractive Index and Group Velocity Metal Coated Dielectric Spherical Nanocomposites”. Iranian Journal of Physics Research, 24(3), 75-87.

His academic citations are a testament to his research impact and scientific contributions.

Research Skills 🔍

Shewa possesses advanced knowledge in condensed matter physics, with strong analytical and problem-solving skills. He is proficient in a range of experimental and theoretical physics techniques. His technical expertise includes programs such as Matlab, Word, Excel, PowerPoint, OpenOffice, and Latex, and he is skilled in computer languages like Python, Fortran, and Gnuplot. He also has experience with Unix systems and software like xmgrace, showcasing his comprehensive research toolset.

Teaching Experience 📘

Shewa’s teaching experience is extensive, having taught various physics courses at the undergraduate and postgraduate levels. He designs engaging lesson plans and works closely with students to help them grasp key concepts in physics. By preparing and grading exams, assignments, and laboratory reports, he ensures students receive constructive feedback for their academic growth. His role as a mentor goes beyond the classroom, advising students on their academic and career paths and supervising their research projects.

Legacy and Future Contributions 🌱

Shewa is committed to leaving a lasting legacy in the fields of nanotechnology, material science, and condensed matter physics. His ongoing research will likely continue to make valuable contributions to the understanding of optical properties and nanocomposite materials. Looking ahead, Shewa is dedicated to mentoring the next generation of scientists and physicists, sharing his knowledge and advancing the boundaries of nanophysics and material science research. Through continuous publication and collaboration, his work is set to influence the scientific community for years to come.

Publications Top Notes

Effect of Tunable Dielectric Function of the Core on Optical Bistability in Small Spherical Metal-Dielectric Composite

  • Authors: Hawi Aboma, Shewa Getachew, Sisay Shewamare
    Journal: Ethiopian Journal of Applied Sciences
    Year: 2025

Investigation Optical Properties of ZnTe@Ag Core-Shell Spherical Nanocomposites Within Varies Dielectric Host Matrices

  • Authors: Tsegaye Atnaf, Shewa Getachew
    Journal: Advances in Materials
    Year: 2024

Investigating the Optical Bistability of Pure Spheroidal Nanoinclusions in Passive and Active Host Matrices

  • Authors: Shewa Getachew, Girma Berga
    Journal: Canadian Journal of Physics
    Year: 2024

Investigation of Refractive Index and Group Velocity Metal Coated Dielectric Spherical Nanocomposites Within Passive and Active Dielectric Cores

  • Authors: Shewa Getachew
    Journal: Iranian Journal of Physics Research (IJPR)
    Year: 2024

Effect of Tunable Dielectric Core on Optical Bistability in Cylindrical Core–Shell Nanocomposites

  • Authors: Shewa Getachew, Junjie Li
    Journal: Advances in Condensed Matter Physics
    Year: 2024

 

 

Song He | High energy physics | Best Researcher Award

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Mr. Song He | High energy physics | Best Researcher Award

Ph.D. student at Huazhong University of Science and Technology | China

Song He is currently a Ph.D. student at Huazhong University of Science and Technology (HUST), specializing in novel radiation detectors and imaging techniques. He has contributed extensively to high-impact journals in the fields of material science and electronics, with innovative research in scintillator development. His work has led to groundbreaking discoveries in enhancing X-ray imaging and fast neutron imaging resolution.

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Early Academic Pursuits 🎓

Song He’s academic journey began with a Bachelor of Engineering in Materials Science and Engineering from China University of Mining and Technology (2015-2019). He continued with a Master of Engineering in Materials and Physics from the same university (2019-2022). Currently, he is pursuing a Ph.D. in Electronic Science and Technology at HUST since 2022. His early education laid a strong foundation for his innovative approach to radiation detection and imaging technology.

Professional Endeavors 💼

Throughout his career, Song He has primarily focused on developing novel radiation detectors and imaging technologies. His work emphasizes improving the performance of scintillators for better X-ray and neutron imaging. He has filed several patents related to his inventions, demonstrating his commitment to transformative research in radiation detection. Despite limited professional collaborations at this stage, his independent contributions have been highly impactful in the scientific community.

Contributions and Research Focus 🔬

Song He’s research primarily revolves around novel radiation detectors and scintillator technologies. In particular, he has developed a new class of scintillators that overcome traditional limitations by using hot exciton molecules (TPE-4Br) and conjugated polymers (PVT) to enhance performance. His contributions have led to breakthroughs in X-ray imaging and fast neutron imaging resolution, significantly advancing the field of radiation detection.

Impact and Influence 🌍

Song He’s work is paving the way for high-resolution imaging technologies that can have a significant impact in fields such as medical diagnostics, nuclear physics, and security imaging. His innovative approaches are influencing both academic research and practical applications. His recent paper in Advanced Functional Materials (DOI: 10.1002/adfm.202503688) received recognition for offering a new solution to long-standing challenges in the radiation detection field.

Academic Citations 📑

Although Song He’s citation index is not formally listed, his work is published in top-tier journals like Advanced Functional Materials, Inorganic Chemistry, Advanced Materials, and The Journal of Physical Chemistry C. The high impact of his research is evident in the citations of his publications, showing their relevance and influence in the scientific community.

Research Skills 🧠

Song He demonstrates exceptional skills in materials science, physics, and electronic technology. His ability to synthesize innovative materials and develop advanced radiation detectors showcases his technical expertise. Additionally, he has practical skills in scintillator synthesis, polymer chemistry, and in-situ polymerization. His experimental design and analytical techniques allow for high-precision imaging, which is crucial for the future of radiation detection.

Awards and Honors 🏅

Currently, Song He has not reported receiving formal awards or honors. However, the significance of his innovative research and published work in high-impact journals positions him as a rising star in his field. His patent applications and scientific contributions hint at a promising future where such recognitions are likely.

Legacy and Future Contributions 🔮

With his cutting-edge research in radiation detectors and imaging technologies, Song He is poised to make long-lasting contributions to both academic and industry sectors. His future work holds the potential for further advancements in medical imaging, nuclear research, and security applications, with his innovative materials providing solutions to longstanding challenges. As his career progresses, Song He is expected to become a significant figure in radiation detection technologies, with lasting impact on both science and society.

Publications Top Notes

High‐Performing Direct X‐Ray Detection Made of One‐Dimensional Perovskite‐Like (TMHD)SbBr₅ Single Crystal With Anisotropic Response

  • Authors: Guangya Zheng, Haodi Wu, Song He, Hanchen Li, Zhiwu Dong, Tong Jin, Jincong Pang, Rachid Masrour, Zhiping Zheng, Guangda Niu et al.
    Journal: Small
    Year: 2025

Hot Exciton‐Based Plastic Scintillator Engineered for Efficient Fast Neutron Detection and Imaging

  • Authors: Song He, Pengying Wan, Hanchen Li, Zizhen Bao, Xinjie Sui, Guangya Zheng, Hang Yin, Jincong Pang, Tong Jin, Shunsheng Yuan et al.
    Journal: Advanced Functional Materials
    Year: 2025

Close‐to‐Equilibrium Crystallization for Large‐Scale and High‐Quality Perovskite Single Crystals

  • Authors: Hang Yin, Mingquan Liao, Yuanpeng Shi, Zhiqiang Liu, Hanchen Li, Song He, Zhiping Zheng, Ling Xu, Jiang Tang, Guangda Niu
    Journal: Advanced Materials
    Year: 2025

BiSBr, an Anisotropic One-Dimensional Chalcohalide Used for Radiographic Detection

  • Authors: Yunmeng Liang, Pang Jincong, Zhang Qingli, He Song, Xu Ling, Luo Wei, Zhiping Zheng, Guangda Niu
    Journal: The Journal of Physical Chemistry C
    Year: 2024

Remarkable Improvement of Thermoelectric Performance in Ga and Te Cointroduced Cu₃SnS₄

  • Authors: Song He, 勇 罗, Liangliang Xu, Yue Wang, Zhongkang Han, Xie Li, Jiaolin Cui
    Journal: Inorganic Chemistry
    Year: 2021