Tag: Physics Excellence Award

Jonas Muheki | Physics and Astronomy | Research Excellence Award

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Mr. Jonas Muheki | Physics and Astronomy | Research Excellence Award

University of Houston | United States

Mr. Jonas Muheki is an emerging researcher in Medical and Biological Physics, currently pursuing his Doctor of Philosophy in Physics at the University of Houston, Texas, USA, where he specializes in developing innovative opto-electromagnetic modalities for cancer therapy. With a strong academic foundation that includes a Master of Science in Physics with specialization in Photonics from Marwadi University, India, and a Bachelor of Science in Physics and Mathematics from Makerere University, Uganda, he has cultivated a multidisciplinary expertise spanning computational physics, photonics, metamaterials, biosensing, and biomedical applications of electromagnetic fields. Jonas has authored and co-authored multiple peer-reviewed journal publications indexed in Scopus and Web of Science, collectively accumulating over 143 citations, demonstrating his emerging influence in advanced sensor design, nanophotonics, graphene-based metasurfaces, and machine-learning-assisted biomedical devices. His notable publications include contributions to journals such as Plasmonics, Optics & Quantum Electronics, and Micromachines, and he has collaborated with international researchers across India, Saudi Arabia, Uganda, and the United States. His work has advanced modern biosensor architectures, solar absorber designs, and terahertz metamaterial-based diagnostic platforms with growing application potential in healthcare, environmental monitoring, and renewable energy. In addition to his research output, Jonas has contributed significantly to teaching and academic development as a Teaching Assistant at the University of Houston and previously as a Physics Lecturer at Kyambogo University in Uganda. He has supervised undergraduate research, reviewed manuscripts for peer-reviewed journals, and actively participates in scientific communities including the American Physical Society and the Gulf Coast Consortia.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

Muheki, J., Wekalao, J., Albargi, H. B., Jalalah, M., Almawgani, A. H. M., & Patel, S. K. (2025). A graphene gold metasurface inspired surface plasmon resonance sensor designed for terahertz applications in sensing and detection of heavy metals in water. (Plasmonics, 20(1), 289–303)

Wekalao, J., Mandela, N., Muheki, J., & Zaid, A. (2025). Design and analysis of a terahertz metasurface-based refractive index sensor for hemoglobin detection with behaviour prediction using polynomial regression. (Plasmonics, 20(4), 2123–2152)

Wekalao, J., Muheki, J., Mandela, N., Kabarokole, P., & Makoye, P. (2025). Machine learning-optimized titanium-based broadband absorber with high-efficiency performance across visible and infrared wavelengths. (Optical and Quantum Electronics, 57(2), 129)

Armghan, A., Jonas, M., Surve, J., Patel, S. K., Aliqab, K., & Alsharari, M. (2023). Refractory material inspired ultra-wideband solar absorber for thermoelectric photovoltaic performance enhancement with ML inspired prediction. (Alexandria Engineering Journal, 73, 461–472)

Alsharari, M., Muheki, J., Armghan, A., Aliqab, K., Surve, J., & Patel, S. K. (2023). Thermal management mechanism employing transparent nanostructures for winter and summer seasons for indoor environments. (International Journal of Thermal Sciences, 193, 108533)

Majhar Ali | Physics and Astronomy | Best Researcher Award

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Dr. Majhar Ali | Physics and Astronomy | Best Researcher Award

Assistant Professor from Jamia Millia Islamia, India

Dr. Majhar Ali is an accomplished Assistant Professor in the Department of Physics at Jamia Millia Islamia, New Delhi, India. With over 17 years of academic and research experience, he has significantly contributed to the fields of nuclear and particle physics, celestial mechanics, and the application of statistical models in high-energy collisions. Dr. Ali’s research expertise spans quark-hadron phase transitions, particle production analysis at ultra-relativistic energies, and the restricted three-body problem under various perturbations. His prolific academic journey includes publishing numerous articles in reputed international journals, participating in prestigious national and international conferences, and contributing to academic administration. Dr. Ali’s recent works on mass variation, relativistic effects, and modified potentials in the restricted three-body problem highlight his dynamic engagement with evolving scientific challenges. Apart from his research, he has developed strong teaching expertise across key physics subjects, including nuclear physics, modern physics, classical dynamics, and nanoscience. His ability to combine theoretical frameworks with practical applications marks him as a significant contributor to his discipline. Dr. Ali’s dedication to his students, administrative responsibilities, and continuous participation in scientific seminars and workshops reflect his commitment to both academic excellence and community development.

Professional Profile

Education

Dr. Majhar Ali has pursued a robust academic path, beginning with a Bachelor of Science (Honors) degree in Physics from Veer Kunwar Singh University, Arrah, India, in 1997. He continued his higher studies at Patna University, where he earned a Master of Science degree in Physics in 1999. His interest in advanced particle physics and statistical mechanics led him to pursue a doctoral degree at Jamia Millia Islamia, New Delhi, where he completed his Ph.D. in Physics in 2010. His doctoral research was focused on “Nucleus-Nucleus Collisions at High and Intermediate Energy: Particle Production, Collective Flow, and De-confinement Phenomenon,” which provided him with a deep understanding of high-energy nuclear collisions and statistical particle production models. His educational background is firmly grounded in both theoretical and experimental physics, which has significantly contributed to his versatile research capabilities. Throughout his academic journey, Dr. Ali has consistently demonstrated a passion for learning and a commitment to expanding his expertise in modern physics, which has continued to guide his teaching and research work in the years that followed.

Professional Experience

Dr. Majhar Ali has amassed extensive professional experience, beginning his academic career as a Senior Research Fellow under the University Grants Commission from 2008 to 2010. He subsequently served as an Assistant Professor in the Department of Physics at Kalindi College, University of Delhi, from 2010 to 2023, where he developed a reputation for academic excellence and mentorship. In 2024, Dr. Ali joined Jamia Millia Islamia as an Assistant Professor, where he continues to teach and lead research initiatives. His teaching portfolio spans more than 17 years, covering core and advanced physics subjects, including nuclear and particle physics, nanoscience and technology, classical dynamics, and statistical mechanics. Additionally, Dr. Ali has contributed significantly to the academic administration of Kalindi College, serving in multiple key roles, such as Deputy Coordinator for the Central Evaluation Center and Convenor of Remedial and Coaching Classes. His administrative responsibilities extended to critical committees focusing on student progress, internships, and anti-ragging policies. Dr. Ali’s professional journey is a blend of dedicated teaching, influential research, and active administrative leadership, demonstrating his commitment to shaping the academic environment and advancing the frontiers of physics.

Research Interests

Dr. Majhar Ali’s research interests encompass a broad range of advanced topics within physics, with particular focus on nuclear and particle physics, celestial mechanics, and statistical methods applied to high-energy collisions. His early work centered on the quark-hadron phase transition models, exploring the behavior of matter under extreme conditions using hadronic resonance gas models. Dr. Ali has also extensively investigated particle production mechanisms across a wide energy spectrum, from intermediate to ultra-relativistic energies, contributing valuable insights to the study of quark-gluon plasma formation. In recent years, his research has pivoted towards celestial mechanics, focusing on the dynamics of the perturbed restricted three-body problem (CR3BP), incorporating relativistic effects, mass variations, and modifications to classical potentials. This interdisciplinary approach bridges nuclear physics and astrophysical dynamics, underscoring his ability to tackle complex, multi-domain scientific challenges. His recent studies also delve into the effects of quantum corrections and variable mass systems in gravitational interactions. Dr. Ali’s research is characterized by the innovative application of mathematical models to solve real-world astrophysical and nuclear physics problems, positioning him as a researcher who contributes to both theoretical advancements and practical understanding within the field of physics.

Research Skills

Dr. Majhar Ali possesses an extensive set of research skills that span both theoretical and applied physics. His proficiency in developing and applying advanced statistical models has been instrumental in analyzing particle production across intermediate to ultra-relativistic energies. He is skilled in using the Hadronic Resonance Gas model to investigate quark-hadron phase transitions, providing valuable contributions to nuclear physics. In celestial mechanics, Dr. Ali demonstrates expertise in modeling the perturbed restricted three-body problem, incorporating relativistic corrections, mass variations, and modified gravitational potentials. He is adept at applying mathematical physics techniques to solve complex dynamical systems and has a strong command of analytical problem-solving in both classical and quantum domains. His research skills also include data interpretation from high-energy physics experiments, critical evaluation of theoretical models, and computational physics methods. Dr. Ali’s multi-disciplinary approach enables him to address a wide array of scientific questions, linking particle physics with astrophysical dynamics. Additionally, his teaching experience across diverse physics subjects has honed his ability to translate complex theoretical concepts into accessible knowledge, benefiting both his research collaborators and his students.

Awards and Honors

Dr. Majhar Ali’s academic journey is decorated with recognitions that reflect his dedication to scientific research and academic excellence. During his early research career, he was awarded the prestigious Senior Research Fellowship by the University Grants Commission, Ministry of HRD, Government of India, from 2008 to 2010, which supported his doctoral studies in nuclear and particle physics. His research presentation on the thermal model and rapidity spectra of hadrons earned him the Third Prize at the Natural Sciences Info-Fest 2007 organized by Jamia Millia Islamia, further recognizing his potential as a promising physicist. Dr. Ali has presented his research at several national and international conferences, including the Quark Matter 2008 Symposium and the DAE-BRNS High Energy Physics Symposium, where his work on multiple fireball formation and proton-antiproton flow was well received. Beyond his research accolades, Dr. Ali has actively contributed to academic seminars, workshops, and webinars, consistently participating in initiatives that foster academic growth and interdisciplinary learning. His awards and recognitions not only highlight his scientific contributions but also his role as a dedicated academic committed to advancing knowledge and nurturing the next generation of physicists.

Conclusion

Dr. Majhar Ali exemplifies the qualities of an outstanding researcher and educator, with a distinguished career that integrates rigorous research, effective teaching, and committed academic leadership. His work spans significant areas in nuclear and particle physics, particularly the study of high-energy collisions and the dynamics of celestial bodies under complex perturbations. His contributions to the understanding of quark-hadron transitions and particle flow dynamics have enriched the scientific community’s knowledge of fundamental physics. Dr. Ali’s professional journey is marked by his dedication to continuous learning, interdisciplinary research, and student mentorship. His consistent participation in conferences, seminars, and academic workshops illustrates his passion for academic engagement and scientific collaboration. Dr. Ali’s ability to balance teaching responsibilities with an active research agenda, along with his substantial administrative experience, further underscores his holistic approach to academia. While opportunities for expanding his international collaborations and research supervision remain areas for potential growth, his current accomplishments and trajectory position him as a valuable contributor to the global physics community. Dr. Majhar Ali is undoubtedly a strong and deserving candidate for recognition under the Best Researcher Award.

Publications Top Notes

1. To Study the Relativistic Effect in the Perturbed Circular Restricted Three-Body Problem

  • Authors: M. Ali, Abdullah, S. Aneja, S. N. Prasad

  • Journal: Modern Physics Letters A, 40(04), 2550027

  • Year: 2025

  • DOI: 10.1142/S0217732325500270

2. Effects of Mass Variation with Loglogistic Distribution in the Perturbed Interacting CR3BP with Heterogeneous Primary and Modified Newtonian Potential of Secondary

3. Analysis of Halo Orbits in the Elliptical R3BP with Mass Variation

  • Authors: M. Ali, et al.

  • Journal: International Journal of Applied Mathematics (Accepted, 9 August 2024)

  • Year: 2024

4. Effects of Modified Potential and Quantum Correction in the Generalized Perturbed Interacting CR3BP with Variable Mass Newtonian Potential of Secondary

  • Authors: M. Ali, et al.

  • Journal: Solar System Research (Accepted, 3 August 2024)

  • Year: 2024

5. Strangeness Production – A Possible Signal of Quark Gluon Plasma Formation

  • Authors: M. Ali

  • Journal: International Journal of Engineering & Scientific Research, 6(3)

  • Year: 2018

6. Net Proton and Charged Meson Flow in Relativistic Heavy Ion Collisions at 200 GeV/A

  • Authors: M. Ali

  • Journal: International Research Journal of Natural and Applied Science, 5(1)

  • Year: 2018

7. Rapidity Distribution of Particles Produced in Ultra-relativistic Nucleus-Nucleus Collisions: A Possible Sequential Freeze-out Scenario

  • Authors: M. Ali

  • Journal: International Journal of Advance Research, 2(3)

  • Year: 2014

8. Longitudinal Hadronic Flow at RHIC in Extended Statistical Thermal Model and Resonance Decay Effects

  • Authors: M. Ali

  • Journal: Acta Physica Polonica B, 41(7)

  • Year: 2010

9. Pion Production and Collective Flow Effects in Intermediate Energy Nucleus-Nucleus Collisions

  • Authors: M. Ali

  • Journal: International Journal of Modern Physics, 21(7)

  • Year: 2006

10. Net Proton Flow and Nuclear Transparency Effects at RHIC: Multi-Fireball Model Approach

  • Authors: M. Ali

  • Repository: arXiv:0901.1376

  • Year: 2009

 

Dandan Wang | Physics and Astronomy | Best Researcher Award

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Assoc. Prof. Dr Dandan Wang | Physics and Astronomy | Best Researcher Award

Associate Professor at Key Laboratory of Functional Materials Physics and Chemistry of Ministry of Education, College of Physics, Jilin Normal University, China

Wang Dandan is an accomplished researcher in the field of physics, specializing in optics and applied physics. With a Ph.D. from the prestigious Chinese Academy of Sciences, she has built a strong academic foundation. Her career spans roles as a postdoctoral researcher and an associate professor, contributing significantly to research and education. She has led multiple research projects funded by national and provincial institutions, demonstrating her ability to secure competitive grants. Recognized as a high-level talent in Jilin Province, Wang has made meaningful contributions to her field through both theoretical and applied research. In addition to her research activities, she serves as a mentor to graduate students, fostering academic development in her institution.

Professional Profile

Education

Wang Dandan earned her bachelor’s degree in physics from Wuhan University in 2010, where she gained fundamental knowledge in classical and modern physics. She then pursued her Ph.D. at the Changchun Institute of Optics, Fine Mechanics, and Physics at the Chinese Academy of Sciences, completing it in 2015. Her doctoral research focused on advanced optical materials and their applications. This rigorous academic training provided her with expertise in experimental and theoretical physics, laying the groundwork for her future research in optics and applied physics.

Professional Experience

Following her Ph.D., Wang Dandan worked as a postdoctoral researcher at the Changchun Institute of Applied Chemistry from 2015 to 2017. During this time, she engaged in interdisciplinary research, further strengthening her expertise in materials science and applied physics. In 2018, she joined Jilin Normal University as an associate professor in the College of Physics. In this role, she has been actively involved in teaching, research, and mentoring graduate students. She has also led several competitive research projects, demonstrating her leadership in scientific investigations.

Research Interests

Wang Dandan’s research primarily focuses on optics, fine mechanics, and applied physics. She is particularly interested in the development and application of optical materials, advanced imaging techniques, and light-matter interactions. Her work also explores new methodologies for enhancing optical system performance, contributing to advancements in both fundamental physics and practical applications. Through her research, she aims to bridge the gap between theoretical studies and real-world implementations, ensuring that her findings contribute to technological advancements.

Research Skills

With extensive experience in experimental physics, Wang Dandan possesses strong analytical and technical skills in optical system design, material characterization, and applied photonics. She is proficient in using advanced spectroscopy techniques, nanofabrication methods, and computational modeling for optical applications. Her expertise extends to interdisciplinary research, integrating physics with chemistry and materials science. Additionally, her leadership in research projects highlights her ability to manage large-scale scientific investigations effectively.

Awards and Honors

Wang Dandan has been recognized as a high-level talent in Jilin Province (Category E), reflecting her outstanding contributions to scientific research and academia. She has also successfully secured funding from the National Natural Science Foundation and the Jilin Provincial Department of Science and Technology, further establishing her credibility as a leading researcher. These achievements underscore her expertise and commitment to advancing knowledge in her field.

Conclusion

Wang Dandan is a dedicated researcher with a strong academic background and significant contributions to physics and optics. Her leadership in funded research projects, combined with her teaching and mentorship roles, highlights her commitment to scientific advancement. While her recognition as a high-level talent strengthens her profile, expanding her international collaborations, publication record, and industry engagement could further enhance her research impact. Overall, she is a highly competent candidate with the potential for continued success in her field.

Publication Top Notes

  1. Acid-catalyzed preparation of silicon-based imprinted polymers on the surface of SERS sensors for selective detection of L-tryptophan

    • Authors: Xinyi Liu, Huiyan Wei, Meiqi Ju, Shuhua Zhang, Hongji Li
    • Year: 2025

  2. Efficient Near-Infrared Luminescence in Cr3+ Activated β-Alumina Structure Phosphor via Multiple-Sites Occupancy

    • Authors: Kai Li, Dandan Wang, Dan Wu, Wenping Zhou, Liangliang Zhang
    • Year: 2025

  3. Flexible Au@Ag/PDMS SERS imprinted membrane combined with molecular imprinting technology for selective detection of MC-LR

    • Authors: Heng Guo, Hongji Li, Mengyang Xu, Dandan Wang, Wei Sun
    • Year: 2025

  4. Bi-ZFO/BMO-Vo Z-scheme heterojunction photocatalysis-PMS bidirectionally enhanced coupling system for environmental remediation

    • Authors: Zhaoxin Lin, Jing Shao, Jianwei Zhu, Dandan Wang
    • Year: 2025
    • Citations: 9

  5. Bi2MoO6/ZnIn2S4 S-scheme heterojunction containing oxygen vacancies for photocatalytic degradation of organic pollutant

    • Authors: Dandan Wang, Zhaoxin Lin, Weiting Yang, Hongji Li, Zhongmin Su
    • Year: 2025
    • Citations: 2

  6. Yellow-Emitting Organic–Inorganic Hybrid Manganese Halides Realized by Br/Cl Composition Engineering

    • Authors: Dandan Wang, Huimin Dong, Liangliang Zhang, Ting Wang, Ming Feng
    • Year: 2025

  7. Highly Stable Flexible SERS-Imprinted Membrane Based on Plasmonic MOF Material for the Selective Detection of Chrysoidin in Environmental Water

    • Authors: Xinyi Liu, Hongji Li, Dandan Wang, Yilin Wu, Wei Sun
    • Year: 2025

  8. Bi2MoO6/MgIn2S4 S-scheme heterojunction with rich oxygen vacancies for effective organic pollutants degradation: Degradation pathways, biological toxicity assessment, and mechanism research

    • Authors: Dandan Wang, Zhaoxin Lin, Weiting Yang, Hongji Li, Zhongmin Su
    • Year: 2025

  9. Highly selective fluorescence turn-on sensor for·thiol compounds detection

    • Authors: Chaowei Zhang, Dandan Wang, Yiduo Chen, Weiting Yang, Zhongmin Su
    • Year: 2024

  10. One-step synthesis of O, P co-doped g-C3N4 under air for photocatalytic reduction of uranium

  • Authors: Guangzhi Zhang, Tao Lei, Dandan Wang, Qiang Xu, Zhongmin Su
  • Year: 2024
  • Citations: 2