Satya Prasad Mishra – Microwave Absorber – Best Researcher Award 

Posted on by AMO Physics

Mr. Satya Prasad Mishra began his academic journey with a Bachelor of Technology in Electronics and Telecommunication Engineering from VSSUT, Burla, Odisha, graduating in 2018 with a commendable CGPA of 8.03/10. Driven by his interest in advanced electromagnetic materials, he pursued a Master of Technology in Electronics and Telecommunication Engineering at IIEST, Shibpur, West Bengal, completing it in 2021 with a CGPA of 9.12/10. His M.Tech thesis focused on Microwave Absorber, laying the groundwork for his current doctoral research. Since 2021, he has been pursuing a PhD at NIT Rourkela, Odisha, under the supervision of Prof. Sudipta Maity, focusing on the design and development of Wideband Microwave Absorber for stealth applications, highlighting a consistent trajectory toward electromagnetic absorber technologies.

💼 Professional Endeavors

Throughout his academic journey, Mr. Mishra has actively engaged in workshops, training, and conferences that enrich his expertise in microwave engineering. His participation in specialized workshops on electromagnetics, antenna engineering, and high-frequency simulations demonstrates his commitment to staying at the forefront of technological advancements. As a Graduate Student Member of IEEE and a member of IEEE’s Antenna and Propagation Society (APS) and Microwave Theory and Techniques Society (MTT-S), he has built a strong professional network to support his research endeavors. His receipt of multiple fellowships, including from MHRD India for both M.Tech and PhD studies, further highlights his professional recognition.

🔬 Contributions and Research Focus

Mr. Mishra’s research is centered on the innovative development of Microwave Absorber TECHNOLOGIES, with a special focus on Wideband Microwave Absorber designed for stealth and other electromagnetic applications. His contributions include the design and characterization of flexible, resistive-ink-based microwave absorbers effective across C and X bands. He has developed dual-layer, resistive-patterned, and textile-based absorbers, advancing the field’s understanding of materials and designs that optimize absorption properties. His research also explores novel fabrication techniques such as inkjet printing on photo paper, which holds promise for scalable and cost-effective Microwave Absorber manufacturing.

🌍 Impact and Influence

Mr. Mishra has made a significant impact in the field of Microwave Absorber research, with his work recognized by prestigious awards such as the “Best Paper Award” at a national conference on Intelligent Systems and IoT. His research presentations at international conferences, including IEEE MAPCON, URSI, and APEMC/INCEMIC, have contributed to the global dissemination of advanced absorber technologies. His innovative approaches in flexible and wideband microwave absorbers have influenced both academic research and potential industrial applications in stealth technology and electromagnetic compatibility.

🏆Academic Cites

Mr. Mishra’s published work in highly regarded journals, including IEEE Microwave Magazine and AEU-International Journal of Electronics and Communications, has garnered notable citations, underscoring the academic relevance and utility of his research in Microwave Absorber development. His publications have served as key references for ongoing research in metamaterial absorbers and related electromagnetic applications, enhancing his academic profile and fostering further inquiry in the community.

🌟 Legacy and Future Contributions

Looking ahead, Mr. Satya Prasad Mishra is positioned to be a leading figure in Microwave Absorber research, with a strong foundation of innovative designs and materials science. His ongoing PhD work promises to deliver advanced solutions for stealth technology and electromagnetic wave management. By continuing to pioneer flexible, wideband, and cost-effective microwave absorbers, his future contributions will likely advance both academic research and practical applications, shaping the future landscape of microwave engineering.

📝Microwave Absorber

Mr. Mishra’s early academic pursuits paved the way for his deep specialization in Microwave Absorber design and fabrication, emphasizing innovative materials like resistive ink and flexible substrates. His professional endeavors and contributions have propelled the development of Wideband Microwave Absorber that are vital for stealth and electromagnetic interference mitigation. The impact and influence of his work are evident in the growing citations and recognition of his Microwave Absorber research across international journals and conferences.

✍️ Notable Publication

📝A flexible low-frequency microwave absorber using resistive ink

Journal: AEU - International Journal of Electronics and Communications

Publication Date: August 2025

📝Metamaterial-Based Microwave Absorbers: The Current State of the Art

Journal: IEEE Microwave Magazine

Publication Date: September 2024

Heshmatollah Yavari – Superconductivity and Superfluidity – Best Researcher Award 

Posted on by AMO Physics

PROF. HESHMATOLLAH YAVARI began his academic journey with a Bachelor of Science in Physics from the University of Tabriz (1990–1994), where he laid a solid foundation in theoretical and applied physics. His intellectual curiosity led him to pursue a Master of Science in Physics at the University of Isfahan (1995–1997), where his thesis focused on Fermi superfluidity in spin-polarized Lithium-6. He continued at the same institution for his PhD (1999–2004), diving deep into temperature-dependent transport and magnetic coefficients in superfluid and superconductor systems, which would become a cornerstone of his lifelong research.

💼 Professional Endeavors

PROF. YAVARI’s professional journey is marked by steady academic growth at the University of Isfahan, starting as an Assistant Professor (2005–2010), rising to Associate Professor (2010–2016), and achieving full Professorship in 2016. His roles have included mentoring graduate students, publishing in high-impact journals, and delivering courses in advanced physics. His profound involvement in research and teaching reflects his unwavering dedication to theoretical physics, particularly in superconductivity and superfluidity.

🔬 Contributions and Research Focus

Prof. Yavari’s research is centered around cutting-edge topics in condensed matter physics. His focus areas include superconductivity and superfluidity, Bose-Einstein condensation, ultracold atomic gases, and quantum transport in strongly correlated systems. He has also ventured into complex phenomena such as Majorana fermions, topological superconductors, and neutron star matter. His work has contributed significantly to the theoretical understanding of superconductivity and superfluidity, helping to explain exotic behaviors in low-temperature and quantum systems.

🌍 Impact and Influence

Through decades of dedication, PROF. HESHMATOLLAH YAVARI has become a leading voice in theoretical physics in Iran and internationally. His influence spans classroom instruction in subjects like quantum mechanics, many-body physics, and quantum field theory, to guiding doctoral theses on cutting-edge quantum phenomena. His scholarly outputs, particularly in superconductivity and superfluidity, have inspired numerous studies and have had a ripple effect on both theoretical and applied physics research.

🏆Academic Cites

Prof. Yavari’s body of work is widely cited in international journals, reflecting the importance and originality of his research in superconductivity and superfluidity. His contributions serve as fundamental references for scientists exploring quantum phase transitions, strongly correlated systems, and optical properties of novel materials. His academic citations underscore his role in advancing theoretical frameworks that support experimental discoveries in quantum physics.

🌟 Legacy and Future Contributions

With a firm academic legacy established at the University of Isfahan, Prof. Yavari continues to inspire the next generation of physicists. His upcoming research will likely delve deeper into quantum coherence, topological matter, and emergent properties of complex systems. His work in superconductivity and superfluidity is expected to remain highly influential, bridging theoretical insights with technological frontiers like quantum computing and ultra-sensitive sensors.

📝Superconductivity and Superfluidity

Prof. Heshmatollah Yavari's groundbreaking contributions to superconductivity and superfluidity have reshaped theoretical understanding in condensed matter physics. His focus on quantum transport, correlated systems, and low-temperature behaviors is deeply rooted in superconductivity and superfluidity, which remains a dominant theme across his academic career. As his research continues to evolve, superconductivity and superfluidity will undoubtedly remain central to his impact on science and innovation.

✍️ Notable Publication

📝Purity of Entangled Photon Pairs in a Semiconductor–Superconductor Heterostructure

Authors: Zahra Saeedi, Heshmatollah Yavari

Journal: Materials Research Bulletin (2025)

Citations: 0

📝Effects of Rashba and Dresselhaus SOCs on Superconductors with Broken Inversion Symmetry

Authors: Heshmatollah Yavari, M. Tayebantayeba

Journal: Physica C: Superconductivity and its Applications (2024)

Citations: 0

📝Impurity and Hybridization Effects in Two-Band Superconductors

Authors: F.A. Renani, Heshmatollah Yavari

Journal: Progress of Theoretical and Experimental Physics (2024)

Citations: 0

📝Three-Body and Coulomb Interactions in a Dipolar Bose-Condensed Gas

Authors: Seyed Mostafa Moniri, Heshmatollah Yavari, Elnaz Darsheshdar

Journal: Annals of Physics (2022)

Citations: 2

Sadiq Ullah – Metamaterials – Best Researcher Award 

Posted on by AMO Physics

Prof. Dr. Sadiq Ullah’s academic journey began with a B.Sc. in Electrical Engineering with distinction from UET Peshawar, Pakistan, followed by an M.Sc. in Electrical Engineering from UET Taxila. His Master’s thesis focused on image and video compression using H.264, reflecting an early interest in signal processing. He completed his PhD at Loughborough University, UK, where his research thesis centered on the design and measurement of metamaterial based antennas, establishing a strong foundation in advanced electromagnetic materials and antenna engineering.

💼 Professional Endeavors

With over 21 years of experience, Prof. Ullah has contributed extensively to academia, research, and industrial administration. His career began as an Assistant Manager in electronics at the National Development Complex, Islamabad, where he led multidisciplinary teams and developed electronic circuits. Transitioning to academia, he served various roles at the University of Engineering & Technology (UET) in Pakistan, rising from Lecturer to full Professor and Pro-Vice Chancellor at UET Mardan. He has also worked internationally as a Research Associate at Loughborough University, UK, and as a Visiting Professor in China, enhancing his global professional impact.

🔬 Contributions and Research Focus

Prof. Ullah’s research primarily focuses on metamaterials, telecommunications, antennas, and electromagnetics. His pioneering work in metamaterials has led to innovative antenna designs with enhanced performance and novel electromagnetic properties. He has published over 120 peer-reviewed papers, with an h-index of 33 and more than 2,950 citations, highlighting his influential contributions to the field. Beyond research, he has played a critical role in curriculum development, establishing MSc and PhD programs, and fostering industry collaborations.

🌍 Impact and Influence

Recognized as one of the world’s top 2% most-cited scientists in telecommunications and electromagnetics by Stanford University, Prof. Ullah’s work has significantly influenced both academia and industry. His leadership roles at UET Mardan, including Pro-Vice Chancellor and Head of the Telecommunication Engineering Department, reflect his strategic impact on engineering education, faculty development, and research excellence. His engagement with IEEE and other professional bodies further amplifies his influence in the global scientific community.

🏆Academic Cites

Prof. Ullah’s extensive publication record and citation metrics underscore his academic influence. With over 2,950 citations and an i10-index of 68, his research on metamaterials and antenna design is widely referenced. His scholarly contributions continue to serve as key references for researchers developing next-generation telecommunication systems and electromagnetic devices.

🌟 Legacy and Future Contributions

Prof. Sadiq Ullah’s legacy is defined by his leadership in advancing metamaterial science, engineering education, and research infrastructure. Looking forward, he aims to continue mentoring future engineers and researchers, expanding his research into novel metamaterial applications for telecommunications, and fostering international collaborations. His vision includes driving innovation in electromagnetic device engineering and strengthening industry-academic partnerships to bridge research and practical implementations.

📝Metamaterials

Prof. Dr. Sadiq Ullah is a leading expert in metamaterials, having significantly advanced antenna design and electromagnetic research through his academic and professional endeavors. His pioneering research in metamaterials underpins much of his scholarly output, influencing the field of telecommunications globally. His continued work and leadership ensure that metamaterials remain at the forefront of emerging technologies in electrical engineering and communication systems.

✍️ Notable Publication

📝Dual-band Cross-polarization and Linear-to-Circular Polarization Converting Metasurface

Authors: Abdullah B., Babar Kamal, Sami Ullah, Ashfaq Ahmad, Dongyou Choi

Journal: Results in Physics (2025)

Citations: 0

📝A Wideband Biconic Shape Metasurface for Polarization Conversion and Radar Cross-Section Reduction

Authors: Haseeba Kanwal, Babar Kamal, Sami Ullah, Amjad Aziz, Zakriya Faraz

Journal: International Journal of Microwave and Wireless Technologies (2025)

Citations: 0

📝High-Isolation Array Antenna Design for 5G mm-Wave MIMO Applications

Authors: Nisar Ahmad Abbasi, Bal Singh Virdee, Iftikhar Ud Din, C.H. See, Mohammad Alibakhshikenari

Journal: Journal of Infrared, Millimeter, and Terahertz Waves (2025)

Citations: 3

📝A Wideband and Low-SAR Antenna Design at 2.45 GHz for Biomedical Applications

Authors: Sami Ullah Khan, Muhammad Aamir, Muhammad Abbas, Abdul Basir, Toni Björninen

Journal: IEEE Open Journal of Antennas and Propagation (2025)

Citations: 0

📝Experimental Validation of a Multi-Functional Metasurface for 5G and Satellite Communication

Authors: Hilal Rauf, Babar Kamal, Sami Ullah, Usman Ali, Ladislau Matekovits

Journal: IEEE Access (2025)

Citations: 0

📝Coverage Probability of C-V2X Network with Full Duplex Communication on BSs over Shared Channels

Authors: Adeel Ahmad, Muhammad Nadeem Sial, Mahshan Zaheer Awan, Sami Ullah

Journal: Telecommunication Systems (2024)

Citations: 0

Mais Ahmed – Nanopartical – Best Researcher Award 

Posted on by AMO Physics

Assist. Prof. Dr. Mais Ahmed has demonstrated a strong commitment to advancing her expertise in biology and biotechnology since her early academic years. She completed her M.Sc. in Biotechnology in 2006 at the University of Baghdad, focusing on microbial enzyme production and its application in biological treatment. Currently, she is pursuing her PhD in the Department of Biology, College of Science, University of Baghdad, concentrating on the antimicrobial and inflammatory effects of bacteriocins derived from multidrug-resistant bacteria such as Pseudomonas aeruginosa and Staphylococcus aureus. Her academic path reflects a dedication to addressing critical biomedical challenges, particularly antimicrobial resistance and wound healing.

💼 Professional Endeavors

Dr. Ahmed's professional endeavors encompass extensive research and development activities in microbiology and biotechnology. She has been actively involved in projects that explore the production and application of bacteriocins and nanoparticles for medical and food industry uses. Her work includes innovative patents such as the production of purified bacteriocins targeting Methicillin-Resistant Staphylococcus aureus (MRSA) and the manufacturing of bio-additives from rosemary essential oil as natural preservatives. Additionally, Dr. Ahmed has pioneered the production of zinc oxide nanoparticles using Staphylococcus epidermidis, achieving nanoscale particle sizes for the first time locally and globally. Her contributions also extend to supervising graduate research projects and participating in academic conferences.

🔬 Contributions and Research Focus

Dr. Mais Ahmed's research is primarily focused on the development and application of nanoparticles and antimicrobial agents to combat multidrug-resistant bacteria and improve wound healing processes. Her patents highlight the significance of nanoparticles and bacteriocins as potent alternatives to traditional antibiotics and chemical preservatives. The focus on zinc oxide nanoparticles demonstrates her innovative approach to leveraging microbial synthesis for advanced biomedical applications. Furthermore, her investigations into the efficacy and safety of natural preservatives provide valuable insights into food safety and public health.

🌍 Impact and Influence

Dr. Ahmed's work has made a considerable impact in both academic and applied biotechnology fields. Her pioneering research on the biological synthesis of nanoparticles and bacteriocins addresses urgent global challenges such as antibiotic resistance and food contamination. Her studies on MRSA and foodborne pathogens like Bacillus cereus have influenced new approaches for antimicrobial treatments and preservative technologies. Through her publications, patents, and conference presentations, she has established herself as a significant contributor to microbiology and biotechnology, inspiring further research and collaboration.

🏆Academic Cites

Dr. Ahmed has published over 18 research articles in international journals indexed by Scopus and Clarivate, indicating strong academic recognition and citation of her work. Her research on nanoparticles, bacteriocins, and antimicrobial agents continues to garner attention in scholarly circles, underscoring the relevance and innovation of her studies. Her academic influence is further demonstrated by her role in supervising graduate students and reviewing research for local journals, contributing to the growth of scientific knowledge in her field.

🌟 Legacy and Future Contributions

Dr. Mais Ahmed's legacy is rooted in her innovative integration of microbiology, biotechnology, and nanoparticle technology to address pressing medical and industrial problems. Her ongoing PhD research promises to yield further breakthroughs in combating antibiotic resistance and enhancing wound healing through biologically derived compounds. Looking forward, her work is expected to continue shaping new biomedical therapies and natural preservative solutions, reinforcing her position as a leading figure in microbial biotechnology and nanoparticles research.

📝Nanopartical

Dr. Mais Ahmed’s pioneering research prominently features nanoparticles, especially in the context of zinc oxide synthesis via microbial routes. Her work on biologically produced nanoparticles has set new benchmarks locally and globally, enhancing antimicrobial and therapeutic capabilities. The application of nanoparticles in her research exemplifies the cutting-edge intersection of microbiology and nanotechnology for health and industrial advancements.

✍️ Notable Publication

📝Bacteriocin Isolated from Ralstonia mannitolilytica and Bacteriocin-Capped Silver Nanoparticles Comparative effects on biofilm formation and LuxS gene expression by Proteus mirabilis as an approach to counter MDR catheter infection

Authors: M.E. Ahmed, A.N. Aljarbou, H.A. Mohammed, R.A. Khan

Journal: Microbial Pathogenesis

Citations: 0

📝Synthesis, Characterization, and Cytotoxic Evaluation of Selenium Nanoparticles

Authors: Z.A. Habeeb, S.K. Jameel, M.E. Ahmed

Journal: Biomedical and Pharmacology Journal

Citations: 0

📝Green Synthesis and Characterization of Selenium Nanoparticles via Staphylococcus warneri

Title: Antimicrobial effects and impact on PhzM pyocyanin gene expression in Pseudomonas aeruginosa

Authors: F.H. Fawzi, M.E. Ahmed

Journal: Plasmonics

Citations: 5

📝Biosynthesized ZnO-CuO Nanocomposite for Biofilm Formation of Proteus mirabilis upon LuxS Gene Expression

Authors: M.E. Ahmed, N.H. Faiq, H.H. Almutairi, M.W. Waqas

Journal: Inorganics

Citations: 1

YueZhuan Liu – Plasma Applying – Best Researcher Award 

Posted on by AMO Physics

Assoc. Prof. Dr. YueZhuan Liu has demonstrated a strong academic foundation beginning with a Bachelor’s degree in Aircraft Manufacturing Engineering from Shenyang Aerospace University (2002–2006). He further pursued a Master’s degree in Aerospace Manufacturing Engineering at the same university (2006–2009), deepening his expertise in advanced manufacturing processes. Dr. Liu’s dedication to research culminated in earning a PhD in Materials Science and Engineering from the University of Science and Technology of China (2010–2016), where he specialized in engineering materials science and technology.

💼 Professional Endeavors

Dr. Liu’s professional career reflects a blend of academic teaching and cutting-edge research. Since 2019, he has served as a faculty member at Ningbo University of Technology in the School of Mechanical and Automotive Engineering, where he teaches key undergraduate courses such as “Fundamentals of Mechanical Manufacturing” and “C Language Programming.” Between 2016 and 2019, he worked as a postdoctoral researcher at the Ningbo Institute of Materials Technology and Engineering under the Chinese Academy of Sciences. His postdoctoral research focused on a significant project addressing “Backstrike protection during laser drilling of film cooling holes,” funded by the Natural Science Foundation of Zhejiang Province. Early in his career, from 2009 to 2010, he contributed to experimental teaching in theoretical mechanics and material mechanics at the Mechanics Laboratory of Shenyang Aerospace University.

🔬 Contributions and Research Focus

Dr. YueZhuan Liu’s research primarily focuses on plasma applying technologies, with a special interest in laser-material interactions and advanced manufacturing processes. His notable project on “Backstrike protection during laser drilling of film cooling holes” exemplifies his contribution to improving manufacturing efficiency and material performance through plasma-assisted processes. His work advances the application of plasma in enhancing material properties and optimizing aerospace manufacturing techniques.

🌍 Impact and Influence

Dr. Liu’s research and academic involvement have made a meaningful impact in the fields of materials science and mechanical manufacturing. His application of plasma technologies in manufacturing has influenced both academic research and industrial practices, especially in aerospace engineering contexts. As an educator, he has nurtured the next generation of engineers, disseminating knowledge of mechanical manufacturing fundamentals alongside programming skills essential for modern engineering.

🏆Academic Cites

His scholarly work has gained recognition in relevant academic circles, particularly in journals and conferences focused on materials engineering and manufacturing technologies. Dr. Liu’s studies on plasma applying techniques and laser drilling methods have been cited for their innovation in improving manufacturing precision and durability of aerospace components.

🌟 Legacy and Future Contributions

Looking forward, Assoc. Prof. Dr. YueZhuan Liu is poised to continue advancing plasma applying technologies in aerospace and mechanical engineering. His ongoing research aims to refine laser processing methods and explore new plasma-assisted manufacturing innovations. Through his teaching and research, Dr. Liu will continue to contribute to the integration of plasma applications in industrial manufacturing, leaving a lasting legacy in materials engineering education and technology development.

📝Plasma Applying

Assoc. Prof. Dr. Liu’s expertise in Plasma Applying techniques has significantly contributed to advancements in aerospace manufacturing processes. His research emphasizes Plasma Applying in laser drilling and material modification, driving innovation in film cooling hole technology. The continuous development of Plasma Applying methods under Dr. Liu’s guidance is expected to transform manufacturing precision and efficiency in the materials science domain.

✍️ Notable Publication

📝Improving superficial microstructure and properties of the laser-processed ultrathin kerf in Ti-6Al-4V alloy by water-jet guiding

Authors: Y. Chao Yang, Yuezhuan Liu, Zifa Xu, Wenwu Zhang, Liyuan Sheng, et al.

Journal: Journal of Materials Science and Technology

Year: 2023

Citations: 44

Babar Kamal – Metasurfaces – Best Researcher Award 

Posted on by AMO Physics

Dr. Babar Kamal’s academic journey is a testament to perseverance, intellectual curiosity, and technical brilliance. He began his studies in Science at the International Education Academy, Swat, followed by Pre-Engineering at Islamia College Peshawar. Demonstrating early promise, he pursued a B.Sc. in Electronics Engineering with distinction from BUITEMS Quetta, Pakistan, where he was awarded multiple scholarships for academic excellence, including a full NICTR&DFund scholarship. His educational trajectory continued with an M.Sc. in Telecommunication Engineering from UET Mardan, where he specialized in the design and SAR analysis of planar wearable antennas using EBG structures an early indicator of his future focus on wave manipulation technologies. He later earned both a Ph.D. and Postdoctoral degree in Information and Communication Engineering from Northwestern Polytechnical University (NWPU), Xi’an, China, specializing in the design and analysis of wideband polarization-converting metasurfaces.

💼 Professional Endeavors

Dr. Babar Kamal’s professional pursuits reflect a consistent dedication to advanced electromagnetic research and academic excellence. His work as a postdoctoral researcher at NWPU further refined his expertise in metamaterials, metasurfaces, and wave manipulation devices. Throughout his academic and professional career, Dr. Kamal has focused on integrating theoretical analysis with experimental validation to develop practical solutions in the fields of wireless communication, radar, and acoustics. His involvement in numerous high-impact research projects and collaborations with leading Chinese and Pakistani institutions underscores his professional commitment to advancing the field of metasurfaces and related electromagnetic technologies.

🔬 Contributions and Research Focus

Dr. Kamal’s research spans a wide range of highly specialized domains, with a central focus on metasurfaces and metamaterials. His contributions include the development of innovative wideband polarization control devices, radar cross-section reduction materials, multiband/wideband and 5G/6G antennas, as well as absorptive and wearable antenna systems. He has also contributed to emerging fields like phase-change materials for electromagnetic wave modulation and acoustic wave control. His ability to bridge the gap between theory and real-world application has resulted in impactful research outcomes in signal processing, network security, and electromagnetic wave propagation.

🌍 Impact and Influence

The scientific community has recognized Dr. Kamal’s impactful research, particularly in the domain of metasurfaces, where his designs have paved the way for more efficient electromagnetic and acoustic devices. His innovations in wearable technology and polarization converters have contributed significantly to the design of next-generation antennas and stealth materials. Dr. Kamal’s work is also instrumental in areas like Radar Cross Section (RCS) reduction and 5G/6G antenna design, influencing both academic research and industrial development across multiple countries. His interdisciplinary research approach strengthens international collaborations, extending his influence beyond borders.

🏆Academic Cites

Dr. Babar Kamal’s research outputs have been widely cited in top-tier journals and international conferences. His extensive work on metasurfaces and wearable antennas has drawn attention from scholars across the fields of telecommunication, electromagnetics, and materials science. The high citation rate of his publications highlights the technical merit and relevance of his work in solving real-world challenges in communication and defense technologies.

🌟 Legacy and Future Contributions

Dr. Kamal’s legacy is rooted in his ability to transform theoretical concepts into practical, scalable innovations in the realm of metasurfaces and metamaterials. His future contributions are poised to address critical challenges in emerging technologies like reconfigurable intelligent surfaces, adaptive antennas, and hybrid electromagnetic-acoustic systems. As a mentor, researcher, and innovator, he continues to inspire the next generation of engineers and scientists, with a vision firmly aligned toward the future of wave-based technologies, particularly in 6G, wearable tech, and secure communication networks.

📝Metasurfaces

Dr. Babar Kamal’s pioneering research in metasurfaces has led to the development of wideband polarization converters and efficient wave-control devices. His innovative approaches to metasurfaces design have broad applications in antennas, stealth technology, and smart materials. Through ongoing research and collaboration, Dr. Kamal continues to redefine the possibilities of metasurfaces, cementing his place as a leading contributor to this transformative field.

✍️ Notable Publication

📝Design, Analysis and Applications of Wearable Antennas: A Review

Authors: U. Ali, S. Ullah, B. Kamal, L. Matekovits, A. Altaf

Journal: IEEE Access, 11, 14458-14486

Year: 2023

Citations: 157

📝Design and SAR Analysis of Wearable Antenna on Various Parts of Human Body Using Conventional and Artificial Ground Planes

Authors: U. Ali, S. Ullah, J. Khan, M. Shafi, B. Kamal, A. Basir, J.A. Flint, R.D. Seager

Journal: Journal of Electrical Engineering and Technology, 12(1), 317-328

Year: 2017

Citations: 114

📝Design and Experimental Analysis of Dual-Band Polarization Converting Metasurface

Authors: B. Kamal, J. Chen, Y. Yin, J. Ren, S. Ullah, U. Ali

Journal: IEEE Antennas and Wireless Propagation Letters, 20(8), 1409-1413

Year: 2021

Citations: 66

📝High Efficiency and Ultra-Wideband Polarization Converter Based on an L-Shaped Metasurface

Authors: B. Kamal, J. Chen, Y. Yingzeng, J. Ren, S. Ullah, W.U.R. Khan

Journal: Optical Materials Express, 11(5), 1343-1352

Year: 2021

Citations: 56

📝Design and Experimental Analysis of Dual-Band Polarization Converting Metasurface for Microwave Applications

Authors: B. Khan, B. Kamal, S. Ullah, I. Khan, J.A. Shah, J. Chen

Journal: Scientific Reports, 10(1), 15393

Year: 2020

Citations: 49

Thirumurugan D – Cancer Drug – Best Researcher Award

Posted on by AMO Physics

Dr. Thirumurugan D. demonstrated a profound interest in microbiology from early on, completing his Bachelor of Science in Microbiology at Urumu Dhanalakshmi College under Bharathidasan University. His foundational education was further strengthened with a Master of Science and Master of Philosophy in Microbiology, focusing on critical issues such as multidrug-resistant Escherichia coli in hospital infections and biocontrol using beneficial microbes. His doctoral research at Bharathidasan University culminated in a PhD thesis on marine actinobacteria from the east coast of India, emphasizing the characterization, optimization, and antibacterial compound production targeting fish pathogenic bacteria. These early academic efforts provided a strong platform for his ongoing research, including aspects relevant to Cancer Drug discovery through microbial metabolites.

💼 Professional Endeavors

With nearly 17 years of teaching and research experience, Dr. Thirumurugan has held significant academic roles in prominent Indian institutions, including Meenakshi Chandrasekaran College, Indo-American College, and SRM Institute of Science and Technology. Throughout his career, he has actively contributed to microbiology and biotechnology education, guiding students and research scholars. He also plays vital roles in doctoral committees and exam evaluations across various universities, demonstrating his expertise and leadership in the microbiology and biotechnology fields, particularly in the discovery and optimization of microbial metabolites with potential as Cancer Drug candidates.

🔬 Contributions and Research Focus

Dr. Thirumurugan’s research has centered on marine actinobacteria—microorganisms known for producing bioactive compounds with pharmaceutical relevance. His pioneering work involves isolating and optimizing antibacterial compounds from these marine microbes, targeting fish pathogens as well as human pathogens. Importantly, his studies delve into exploring these microbial compounds as promising sources for Cancer Drug development. Through extensive screening, isolation, and purification techniques, he has contributed valuable insights to microbial biotechnology, with an emphasis on natural products that could transform cancer treatment strategies.

🌍 Impact and Influence

Dr. Thirumurugan’s contributions have impacted both academia and applied science by advancing microbial biotechnology and natural product research. His research on marine actinobacteria has enhanced understanding of microbial biodiversity and its pharmaceutical potential. Moreover, by focusing on antibacterial compounds with possible anticancer properties, he bridges the gap between environmental microbiology and medical therapeutics. His influence is evident in his involvement in organizing seminars, training programs, and blood grouping camps, which emphasize community health and scientific outreach.

🏆Academic Cites

His scientific work has been widely disseminated through national and international conferences and seminars, where he has presented numerous research papers on antibacterial and antifungal activities of marine actinomycetes. These contributions have been cited by researchers exploring novel microbial metabolites, including potential Cancer Drug leads. Dr. Thirumurugan’s research has strengthened the repository of knowledge on natural bioactive compounds, underscoring the value of marine microbes in biomedicine.

🌟 Legacy and Future Contributions

Looking forward, Dr. Thirumurugan is poised to further expand his research into the bioprospecting of marine microorganisms for novel bioactive compounds, particularly those with anticancer potential. His dedication to teaching and mentoring the next generation of scientists ensures his academic legacy will persist. Future endeavors will likely focus on enhancing the therapeutic efficacy and production optimization of microbial metabolites, contributing significantly to the discovery and development of new Cancer Drug candidates with improved safety and efficacy profiles.

✍️ Notable Publication

📝An Introductory Chapter: Secondary Metabolites

Source: Book chapter in Secondary Metabolites: Sources and Applications

Year: 2018

Citations: 292

📝Isolation and Identification of Nicotine from Leucas aspera (Willd) Link

Journal: Indian Journal of Pharmaceutical Sciences

Year: 2006

Citations: 46

📝Isolation, Structure Elucidation and Antibacterial Activity of Methyl-4,8-dimethylundecanate from Marine Actinobacterium Streptomyces albogriseolus ECR64

Journal: Microbial Pathogenesis

Year: 2018

Citations: 38

📝Characterization and Structure Elucidation of Antibacterial Compound of Streptomyces sp. ECR77 Isolated from East Coast of India

Journal: Current Microbiology

Year: 2015

Citations: 36

📝DNA Barcoding of Five Japanese Encephalitis Mosquito Vectors

Journal: Acta Tropica

Year: 2018

Citations: 32

📝Padina boergesenii-Mediated Copper Oxide Nanoparticles Synthesis with Antibacterial and Anticancer Potential

Journal: Biomedicines

Year: 2023

Citations: 23

📝Impact of Biosurfactant Produced by Bacillus spp. on Biodegradation Efficiency of Crude Oil and Anthracene

Journal: Chemosphere

Year: 2023

Citations: 21

Tikaram Neupane – Light Matter Interaction – Best Researcher Award 

Posted on by AMO Physics

Assist. Prof. Dr. Tikaram Neupane embarked on his academic path with a strong foundation in physics, culminating in a Ph.D. in Condensed Matter and Optical Physics from Hampton University (2016–2020). His dissertation focused on the third-order optical nonlinearity of tungsten and molybdenum disulfide atomic layers, highlighting his early interest in light-matter interaction phenomena. Prior to this, he earned an MS in Condensed Matter Physics from the University of Wyoming and a Post Graduate Diploma in Earth System Physics from the International Center for Theoretical Physics, Trieste, Italy. His early research projects spanned from quantum materials to geophysical modeling, setting a multidisciplinary foundation for his future work.

💼 Professional Endeavors

Since 2021, Dr. Neupane has served as Assistant Professor of Physics at The University of North Carolina at Pembroke, where he is responsible for teaching, coordinating applied physics programs, and actively recruiting undergraduate students. He also held a postdoctoral research associate position at The University of Southern Mississippi, focusing on ocean optics, ocean color, and remote sensing in collaboration with NASA’s Stennis Space Center. Dr. Neupane’s leadership roles extend beyond academia as he directs regional science fairs, organizes international conferences, and serves on editorial boards and scientific committees.

🔬 Contributions and Research Focus

Dr. Neupane’s research centers on light-matter interaction in low-dimensional materials and nanostructures. His Ph.D. work explored nonlinear optical properties, including nonlinear absorption and refraction in atomic layers and quantum dots, UV/Visible absorption, photoluminescence studies, and all-optical switching mechanisms. He has demonstrated advanced phenomena such as polarization-controlled four-wave mixing and second-order hyperpolarizability via self-phase modulation, contributing substantially to the understanding of photon interactions at the nanoscale. His expertise also spans ocean optics and remote sensing, showcasing the breadth of his research in light-matter interaction.

🌍 Impact and Influence

Dr. Neupane’s research has had significant impact both in condensed matter physics and applied optics. His work is recognized through awards like the Best Presentation Award at the International Conference on Nanoscience and Nanotechnology (ICNST) in 2019 and multiple research grants from NASA and the Department of Defense. His leadership in organizing scientific conferences, serving as guest editor for special journal issues, and evaluating prestigious scholarships reflects his broad influence on the scientific community. His active role in science fairs and community outreach promotes STEM education and inspires the next generation of physicists.

🏆Academic Cites

Dr. Neupane’s publications on light-matter interaction phenomena in nanoscale materials have been cited extensively, underscoring the relevance and innovation of his research. His experimental and theoretical insights into nonlinear optical processes contribute to foundational knowledge utilized by researchers worldwide. These citations reflect the growing recognition of his contributions to the fields of condensed matter physics and applied photonics.

🌟 Legacy and Future Contributions

Looking ahead, Dr. Tikaram Neupane is poised to continue making pioneering contributions to light-matter interaction research, focusing on novel quantum materials and optical phenomena with potential applications in photonics and quantum technologies. His commitment to mentoring students, advancing interdisciplinary research, and fostering scientific collaborations ensures a lasting legacy in both academia and applied physics. As Chair of the 8th ANPA International Physics Conference in 2025, he will further strengthen international scientific dialogue and innovation.

📝Light Matter Interaction

Dr. Neupane’s work significantly advances the understanding of light-matter interaction in atomic layers and quantum dots, driving innovations in nonlinear optics and photonics. His research explores fundamental light-matter interaction mechanisms, such as four-wave mixing and self-phase modulation, providing insights crucial for next-generation optical devices. Through his academic and leadership roles, Dr. Neupane promotes cutting-edge research in light-matter interaction, bridging theoretical physics and practical applications.

✍️ Notable Publication

📝Spatial Self-Phase Modulation in WS2 and MoS2 Atomic Layers

Authors: T. Neupane, B. Tabibi, F.J. Seo

Journal: Optical Materials Express, 10(4), 831–842

Year: 2020

Citations: 27

📝Piezoelectricity Enhancement and Bandstructure Modification of Atomic Defect-Mediated MoS2 Monolayer

Authors: S. Yu, Q. Rice, T. Neupane, B. Tabibi, Q. Li, F.J. Seo

Journal: Physical Chemistry Chemical Physics, 19(35), 24271–24275

Year: 2017

Citations: 17

📝Spatial Self-Phase Modulation in Graphene-Oxide Monolayer

Authors: T. Neupane, B. Tabibi, W.J. Kim, F.J. Seo

Journal: Crystals, 13(2), 271

Year: 2023

Citations: 16

📝Second-Order Hyperpolarizability and All-Optical-Switching of Intensity-Modulated Spatial Self-Phase Modulation in CsPbBr1.5I1.5 Perovskite Quantum Dot

Authors: T. Neupane, H. Wang, W.W. Yu, B. Tabibi, F.J. Seo

Journal: Optics & Laser Technology, 140, 107090

Year: 2021

Citations: 14

📝Third-Order Optical Nonlinearity of Tungsten Disulfide Atomic Layer with Resonant Excitation

Authors: T. Neupane, S. Yu, Q. Rice, B. Tabibi, F.J. Seo

Journal: Optical Materials, 96, 109271

Year: 2019

Citations: 10

📝Cubic Nonlinearity of Molybdenum Disulfide Nanoflakes

Authors: T. Neupane, Q. Rice, S. Jung, B. Tabibi, F.J. Seo

Journal: Journal of Nanoscience and Nanotechnology, 20(7), 4373–4375

Year: 2020

Citations: 5

📝Spin-Resolved Visible Optical Spectra and Electronic Characteristics of Defect-Mediated Hexagonal Boron Nitride Monolayer

Authors: S. Yu, B. Tabibi, Q. Li, F.J. Seo

Journal: Crystal, 12, 906

Year: 2022

Citations: 3

📝Cubic Nonlinearity of Graphene-Oxide Monolayer

Authors: T. Neupane, U. Poudyal, B. Tabibi, W.J. Kim, F.J. Seo

Journal: Materials, 16(20), 6664

Year: 2023

Citations: 2

Yongzhen Liu – Aerothermodynamics – Best Researcher Award 

Posted on by AMO Physics

Assist. Prof. Dr. Yongzhen Liu began his academic journey with a strong interest in thermal and fluid dynamics, which led him to pursue advanced studies in Aerothermodynamics. He earned his Ph.D. in Engineering Thermophysics from the University of Chinese Academy of Sciences in 2021, where he developed a keen interest in aero-engine performance and internal flow mechanisms. During his master’s and doctoral studies, he focused extensively on the internal flow characteristics in the cascade of supersonic compressors, laying a robust theoretical and experimental foundation in high-speed fluid dynamics and compressor aerodynamics.

💼 Professional Endeavors

Dr. Yongzhen Liu is currently a senior engineer at the School of Vehicle and Transportation, Tsinghua University, one of China's premier institutions. Between 2021 and 2024, he completed postdoctoral research at the same university, where he honed his expertise in Aerothermodynamics of aero engines. As a key contributor to over ten major projects including the National 863 Key Project, the National Natural Science Foundation Project, and strategic programs of the Chinese Academy of Sciences he has established himself as a vital asset in national scientific and engineering research initiatives.

🔬 Contributions and Research Focus

Dr. Liu’s research is centered on Aerothermodynamics, particularly the internal flow mechanics of high-load supersonic compressors. He has made groundbreaking contributions in developing a novel compressor design method based on the principle of low-loss shock wave supercharging. His research spans aerodynamic design, stability analysis, flow control, and loss mechanism studies of advanced compressors. These contributions address key challenges in modern propulsion systems and play a crucial role in improving aero engine performance and efficiency.

🌍 Impact and Influence

The impact of Dr. Liu’s work is far-reaching within both academic and engineering communities. His pioneering efforts in Aerothermodynamics have influenced the design protocols of next-generation compressors and advanced propulsion systems. His involvement in nationally significant projects reflects the strategic importance of his research. Moreover, his innovations have not only advanced theoretical understanding but have also been translated into practical applications, enhancing China's aerospace capabilities.

🏆Academic Cites

To date, Dr. Liu has published more than ten academic papers and has applied for nearly five invention patents, several of which have been authorized. His scholarly contributions are widely cited by fellow researchers and continue to serve as a foundation for ongoing advancements in the field of Aerothermodynamics. He has also contributed to the academic community through the translation of three major works, facilitating cross-lingual knowledge dissemination in engineering thermophysics.

🌟 Legacy and Future Contributions

Looking ahead, Dr. Yongzhen Liu is poised to become a leading figure in Aerothermodynamics research. His commitment to high-impact research, combined with his achievements in compressor design and aero engine performance, sets a strong precedent for future innovations. As an academic mentor and engineering visionary, he is expected to guide the next generation of aerospace engineers while continuing to advance cutting-edge technologies in the field.

📝Aerothermodynamics

Dr. Yongzhen Liu’s research in Aerothermodynamics has significantly contributed to the understanding of supersonic compressor behavior and low-loss shock wave mechanisms. His innovative methods in Aerothermodynamics have enhanced both the theoretical and applied dimensions of aero engine development. The continued evolution of Aerothermodynamics will be strongly influenced by his groundbreaking research and technical contributions.

✍️ Notable Publication

📘 An Investigation of the Promotion of the Aerodynamic Performance of a Supersonic Compressor Cascade Using a Local Negative-Curvature Ramp

Authors: YongZhen Liu, Zhen Fan, Weiwei Cui, Qiang Zhou, Jianzhong Xu

Journal: Applied Sciences

Date: May 2025

Barry Clarke – Strings – Best Researcher Award 

Posted on by AMO Physics

Dr. Barry Clarke demonstrated exceptional academic promise from an early stage. He earned a B.Sc. in Theoretical Physics from the University of Hull (1979–1981), achieving an outstanding 90% in Advanced Mathematics an accolade attained by only 4 out of 92 students. His M.Sc. in Theoretical Physics (1982–1984), also from Hull, focused on Commutator Techniques of Quantum Mechanics, including matrix mechanics and Fortranalgorithms. Later, combining his deep scientific mindset with literary scholarship, Dr. Clarke earned a PhD in Shakespeare Studies from Brunel University in 2013, exploring Francis Bacon’s contribution to three Shakespeare plays. This diverse academic foundation laid the groundwork for his multifaceted career.

💼 Professional Endeavors

Dr. Clarke’s career spans academic physics, literary scholarship, popular puzzle writing, and television consultancy. He has published peer-reviewed articles in both quantum mechanics and literary criticism, including pieces in J. Phys. A: Math. Gen., Modern Physics Letters B, and Quantum Studies: Mathematics and Foundations. Simultaneously, he has contributed extensively to public engagement with logic and mathematics through puzzle columns in The Daily Telegraph and other major outlets. His consultancy roles with the BBC and Channel 4 showcase his cross-disciplinary appeal and ability to bring complex ideas into accessible formats.

🔬 Contributions and Research Focus

Dr. Clarke’s dual research focus on quantum physics and Shakespearean authorship sets him apart. His early physics work includes innovations in perturbation theory, matrix mechanics, and fine structure modeling, with a standout recent article on a photonic toroidal vortex model of the hydrogen atom. On the literary front, his 2019 book Francis Bacon’s Contribution to Shakespeare proposed a novel attribution method, endorsed by Sir Mark Rylance. Furthermore, he has written over 1,500 puzzles, authored numerous bestselling books, and continues to write puzzle columns that incorporate strings of logical reasoning and numerical patterns, inspiring critical thinking across ages.

🌍 Impact and Influence

Dr. Clarke’s influence is felt in academic, popular, and interdisciplinary spheres. His physics research is cited in quantum mechanics literature, while his Shakespeare studies have generated lively debate. In the realm of puzzles and logic, his bestsellers—such as Brain Busters and Challenging Logic Puzzles Mensa—have sold over 100,000 copies, some reaching No. 1 on Amazon. His enduring role at The Daily Telegraph and frequent contributions to New Scientist and Reader’s Digest reflect a broad impact across education, publishing, and media.

🏆Academic Cites

His scholarly works, notably those on anharmonic oscillators and quantum perturbation theory, are frequently cited by physicists. His literary critiques, especially on The Tempest and Bacon’s influence, are recognized within Shakespeare studies. The interplay of theoretical strings of logic, whether in matrix mechanics or authorship attribution, ties his academic work together. His book The Quantum Puzzle and article on the Grangier experiment reinterpretation further attest to a rigorous yet innovative approach.

🌟 Legacy and Future Contributions

Looking forward, Dr. Clarke continues to expand his puzzle repertoire with upcoming titles like Tesla’s Puzzles (2026) and Newton’s Puzzles (2024), merging scientific legacy with interactive learning. His work offers a rare fusion of rigorous analytical thinking and creative literary insight. The expected publication of Mathematical Conundrums in 2023 underscores his lasting influence on both mathematics education and recreational problem-solving. His ongoing contributions to physics through new string-based interpretations of quantum models will likely inspire further theoretical development.

📝Strings

Dr. Clarke’s approach to quantum mechanics consistently involves strings of matrix perturbations and logical inference, both in physics and in Shakespeare studies. His puzzles challenge solvers to uncover hidden strings of logic that test cognitive flexibility. Furthermore, his string-based models in quantum physics represent a bridge between classical interpretations and modern theoretical frameworks. The use of strings as a conceptual and practical tool underscores the thematic and methodological unity across his diverse body of work.

✍️ Notable Publication

📝Reinterpretation of the Grangier experiment using a multiple-triggering single-photon model

Author: Barry R. Clarke

Journal: Modern Physics Letters B

Year: 2023

Citations: 0