Month: March 2025

Orcid

🎓 Early Academic Pursuits

Dr. Tripathi’s academic journey began with his B.Sc. in Physics, Chemistry, and Mathematics (1995), followed by an M.Sc. in Physics (1997), specializing in Electronics. His desire to further explore the field of physics led him to pursue an M.Phil. in Physics (2008) and a Ph.D. in Physics (2013) under the guidance of Prof. J.M. Keller and Dr. K. Das at Rani Durgawati University, Jabalpur, where he conducted impactful research on polymeric materials and their optical properties.

💼 Professional Endeavors

Dr. Tripathi has held numerous academic positions, serving as Vice Principal, Assistant Professor, Dean Academics, and Officiating Principal at St. Aloysius Institute of Technology, Jabalpur, before taking on his current role at IPS Academy. He has been an active member of various institutional committees, including the Board of Governors and NAAC accreditation committees. His leadership in these positions demonstrates his commitment to enhancing the quality of education and academic administration.

🔬 Contributions and Research Focus

Dr. Tripathi’s research interests are centered around the preparation, characterization, and application of thin polymer films doped with fluorescent dyes, as well as magnetic nanomaterials like FeS2 nanoparticles and magnetic nanocaps. His research projects include studies on spin-dependent magnetic properties and nanostructures. He is currently leading several high-impact research projects funded by institutions such as UGC-DAE and TEQIP-III, and has co-supervised PhD students on topics ranging from polymeric composites to magnetic nanostructures.

🌍 Impact and Influence

Dr. Tripathi’s work has had a lasting impact on the field of materials science and condensed matter physics, particularly in the study of polymer blends and nanomaterials. He has made significant contributions to advanced research techniques and characterization methods such as XPS, XRD, and UV-Vis spectrophotometry. His research has helped to advance optical materials and magnetic properties, making him a valuable resource in both academia and research communities.

📚 Academic Cites

Dr. Tripathi’s work has garnered numerous citations, underscoring the significance of his research in polymer science and nanotechnology. His publications and research findings are widely referenced by peers, especially in the domains of thin films, nanoscience, and magnetic materials. His ongoing research and collaborations continue to contribute to the advancement of fundamental and applied physics.

🔧 Research Skills

Dr. Tripathi possesses extensive expertise in polymer film deposition, nanostructure synthesis, and magnetic characterization techniques. His research skills include proficiency in advanced instrumentation such as Abbey’s refractometer, microhardness testers, and double-beam UV-Vis spectrophotometers. He is also skilled in nanomaterial characterization and experimental physics, which enable him to conduct cutting-edge research in the field of condensed matter physics.

🍎 Teaching Experience

With over 20 years of teaching experience, Dr. Tripathi has taught undergraduate and postgraduate students in Physics at various institutions, including IPS Academy, St. Aloysius College, and Oriental Group of Institutes. He has been responsible for mentoring students in both classroom teaching and laboratory work, with a focus on experimental physics, nuclear physics, and solid-state physics. He has also been actively involved in organizing national workshops and laboratory training sessions for postgraduate teachers.

🏆 Awards and Honors

Dr. Tripathi has received recognition for his academic and professional contributions, including being appointed as the Chairperson and Convener for numerous conferences and workshops. His leadership has been instrumental in organizing events such as the National Conference on Physics and Chemistry of Materials (2020) and the Prof. Babulal Saraf Memorial All India Laboratory Workshop for P.G. Teachers. His dedication to academic excellence has earned him several accolades from both his peers and academic institutions.

🏛️ Legacy and Future Contributions

Dr. Tripathi’s legacy is built upon his dedication to both teaching and research, having nurtured several Ph.D. scholars and developed a strong academic network. Moving forward, he is committed to making further contributions in nanoscience, polymeric materials, and magnetic nanostructures, while continuing to mentor the next generation of researchers. His future research endeavors aim to address challenges in material science and contribute to innovations in technology commercialization and sustainable development.

Publications Top Notes

Influence of interface alloy formation on the magnetic and structural properties of Co/Si (100) thin films
Authors: Sharma, A., Tripathi, J.
Journal: Interactions, 2024
Dielectric properties of pure PMMA and Co3O4 nanoparticles-PMMA composite films
Authors: Rajput, S.S., Mishra, A., Sharma, A., Singh, J., Tripathi, J.
Journal: Interactions, 2024
Correlation between morphology and transport properties of Au/Co/Au/Si wedge ultra-thin film
Authors: Sharma, A., Tripathi, J., Singh, J., Bisen, R., Tripathi, S.
Journal: Physica B: Condensed Matter, 2024
Curvature modulated structural and magnetic properties of CoO/Co thin films deposited onto 2-D nanosphere array
Authors: Tripathi, J., Kumar, Y., Kumar, D., Sharma, R., Sharma, A.
Journal: Journal of Magnetism and Magnetic Materials, 2023
Synthesis and characterization of zirconia nanocrystalline powder by thermal treatment method
Authors: Soni, D., Singh, J., Kaurav, N., Tripathi, J., Sharma, A.
Journal: Materials Today: Proceedings, 2022

Sheng Hsiung Chang | Experimental methods | Best Researcher Award

Published on 12/03/2025 by High Energy Physics

Prof. Sheng Hsiung Chang | Experimental methods | Best Researcher Award

Professor at National Taiwan Ocean University | Taiwan

Dr. Sheng Hsiung Chang is a Professor at the National Taiwan Ocean University. His extensive career in academia and research is marked by significant roles in leading institutions such as Chung Yuan Christian University (CYCU) and National Central University. Dr. Chang’s work has spanned across several pivotal research areas, particularly in semiconductor physics, optical physics, and perovskite optoelectronic devices. His achievements not only demonstrate his technical expertise but also highlight his commitment to academic leadership, mentorship, and advancing scientific knowledge.

Profile

Early Academic Pursuits 🎓

Dr. Chang’s academic journey began with his postdoctoral research roles, first at Academia Sinica (2008-2010) and later at National Central University (2010-2012), where he gained foundational experience in semiconductor and optical physics. During these early years, he developed a strong interest in light-material interactions and functional thin films, fields that would shape his future research directions. His foundational work in nanotechnology and optoelectronics established the groundwork for his later academic and research career.

Professional Endeavors 🌍

Dr. Chang has held pivotal roles in academia, including Associate Professor and Professor at CYCU, where he also served as the Director of the Career Service Center (2020-2021). These positions reflect his commitment to fostering both the research and professional development of students. Additionally, he has contributed to the scientific community as an Editorial Board Member for journals such as Nanotechnology and Physics Bimonthly.

He has also demonstrated leadership in academic societies, serving as Vice Chairman (2021-2024) and Secretary General (2019-2020) of the Taiwan Vacuum Society. This involvement shows his dedication not only to research but also to promoting collaboration and innovation within the scientific community.

Contributions and Research Focus 🔬

Dr. Chang’s research is centered around perovskite optoelectronic devices, light-material interactions, plasmonic devices, nonlinear optics, and functional thin films. He is currently the Principal Investigator for various research projects funded by the National Science and Technology Council (NSTC) and the Ministry of Science and Technology (MOST). His groundbreaking work on perovskite thin films and their applications in photovoltaic cells is pushing the boundaries of renewable energy technologies. Through projects that explore optical coupling, material interfaces, and energy harvesting, Dr. Chang’s research is expected to revolutionize the optoelectronics field.

Impact and Influence 🌍

Dr. Chang’s contributions to the scientific community have had far-reaching implications, particularly in the area of perovskite solar cells. His work on improving photovoltaic performance and investigating interfacial contacts between organic and inorganic materials has the potential to enhance solar cell efficiency and sustainability. He is a key player in advancing technologies related to energy conversion, helping to foster sustainable solutions to global energy challenges. His leadership roles in academic societies have also expanded his influence and outreach in the scientific community.

Academic Citations 📈

Dr. Chang has an impressive publication record, with recent articles in high-impact journals such as Nanotechnology, Synthetic Metals, and Materials Science in Semiconductor Processing. His work is frequently cited by fellow researchers in the field of optoelectronics, particularly his studies on perovskite materials and their optical properties. These citations underscore the significance and influence of his research in both academia and industry.

Research Skills 🧑‍🔬

Dr. Chang possesses an extensive skill set in semiconductor physics, optical physics experiments, and theoretical computations. His research involves complex techniques such as material synthesis, thin film fabrication, and optical characterization. He has a deep understanding of light-matter interactions and their application to next-generation devices like solar cells and plasmonic devices. Additionally, his ability to bridge experimental techniques with theoretical models allows him to tackle complex challenges in material design and optoelectronic applications.

Teaching Experience 🏫

In his roles as a Professor and Associate Professor, Dr. Chang has mentored numerous graduate and postgraduate students in their research pursuits. His teaching approach is centered around encouraging critical thinking, innovation, and hands-on experimentation. His experience in guiding students and fostering academic growth aligns with his belief in the importance of collaboration and mentorship within academic settings. He also plays an active role in career development, helping students transition into the professional world with a strong foundation in research and industry-related skills.

Awards and Honors 🏆

Throughout his career, Dr. Chang has been the recipient of several prestigious awards and honors, recognizing his contributions to the fields of optical physics, semiconductor research, and perovskite optoelectronics. His ongoing recognition as a leader in nanotechnology and materials science reflects his consistent pursuit of excellence in both academic research and scientific innovation.

Legacy and Future Contributions 🔮

Dr. Chang’s work is poised to leave a lasting impact on the scientific community, particularly in the field of renewable energy and optoelectronics. As the principal investigator of major research projects, he is advancing the efficiency and sustainability of perovskite-based technologies, paving the way for affordable and efficient solar energy solutions. Dr. Chang’s future contributions to nanomaterials and functional thin films will likely continue to inspire scientific innovation, technological advancements, and environmental sustainability for years to come.

Publications Top Notes

Long room-temperature valley lifetimes of localized excitons in MoS2 quantum dots

Authors: H. Wang, Y. Chen, T.Y. Pan, Y. Lee, J. Shen
Journal: Optics Express
Year: 2024

Structural and excitonic properties of the polycrystalline FAPbI3 thin films, and their photovoltaic responses

Authors: Y. Huang, I.J. Yen, C. Tseng, A. Chandel, S.H. Chang
Journal: Nanotechnology
Year: 2024

Observations of two-dimensional electron gases in AlGaN/GaN high-electron-mobility transistors using up-converted photoluminescence excitation

Authors: Y. Chen, L. Chen, C.B. Wu, Y.J. Lee, J. Shen
Journal: Optics Express
Year: 2024

Efficient Optical Coupling between Dielectric Strip Waveguides and a Plasmonic Trench Waveguide

Authors: J. Wu, A. Chandel, C. Chuang, S.H. Chang
Journal: Photonics
Year: 2024

Enhancing the photovoltaic responses of MAPbI3 poly-crystalline perovskite films via adjusting the properties of PEDOT:PSS hole transport material with a low-polarity solvent treatment process

Authors: C. Tsai, S.N. Manjunatha, M. Sharma, L.B. Chang, C. Chang
Journal: Materials Science in Semiconductor Processing
Year: 2024

Ramadevi Suguru Pathinti | Experimental methods | Best Researcher Award

Published on 12/03/202512/03/2025 by High Energy Physics

Mrs. Ramadevi Suguru Pathinti | Experimental methods | Best Researcher Award

Research Scholar at National Institute of Technology Warangal | India

Ramadevi Suguru Pathinti is currently pursuing her Ph.D. in Physics at the National Institute of Technology, Warangal, India, specializing in Materials Science with a focus on soft matter research. Her academic journey spans from her M.Sc. in Physics to her ongoing doctoral studies. Ramadevi has made significant contributions in the field of nanomaterials and smart materials, particularly in integrating liquid crystals with metal oxides for the development of advanced gas sensors and UV photodetectors.

Profile

Early Academic Pursuits 🎓

Ramadevi’s academic journey began at Rayalaseema University, Kurnool, India, where she pursued her M.Sc. in Physics with a specialization in Electronics, securing a CGPA of 9.1/10. She also holds a B.Sc. in Mathematics, Physics, and Computer Science. Her strong academic foundation laid the groundwork for her pioneering research in Materials Science during her doctoral studies at NIT, Warangal.

Professional Endeavors 💼

In her professional journey, Ramadevi has excelled in scientific research within both academic and industrial contexts. She has contributed to the development of thin film devices for smart window technologies, gas sensors, and photodetectors. Her Ph.D. research focuses on integrating liquid crystal-functionalized metal oxides to enhance the optical properties and responsivity of sensors, enabling advancements in environmental sensing and optoelectronic devices.

Contributions and Research Focus 🔬

Ramadevi’s research is centered on the synthesis of nanomaterials and their integration into innovative smart materials. She has worked extensively on fabricating gas sensors and UV photodetectors using liquid crystal-metal oxide hybrids. Notably, her work on smart windows is groundbreaking, where she has discovered novel optical switching behaviors and light modulation techniques, paving the way for energy-saving technologies. Furthermore, her synthesis methods like sol-gel and hydrothermal techniques have contributed to enhanced material properties for sensing applications.

Impact and Influence 🌍

Her research has already made a considerable impact in the fields of environmental sensing and smart material development, particularly in the energy-efficient technologies sector. Ramadevi’s work has the potential to revolutionize how we detect gases, modulate light, and develop self-powered sensors, with applications ranging from smart windows to sensitive environmental monitoring systems. Through her research, she aims to bring forth sustainable technologies that are adaptable to changing global needs.

Academic Cites 📚

Ramadevi has authored several impactful publications in top-tier peer-reviewed journals, contributing to the fields of materials science and optoelectronics. Her articles in journals like the Journal of Molecular Liquids, Journal of Alloys and Compounds, and Advanced Material Technology have contributed to the scientific community’s understanding of the integration of nanomaterials and liquid crystals for innovative devices. She has also presented her research at national and international conferences, further strengthening her academic profile.

Research Skills 🛠

Ramadevi has developed extensive technical expertise in nanomaterial synthesis using methods like sol-gel and hydrothermal techniques. She is proficient in device fabrication, particularly thin film devices for gas sensing and UV photodetector applications. Additionally, she has hands-on experience with advanced research instruments, including optical polarizing microscopes, fluorescence microscopes, and spin coating systems, which enhance her ability to conduct high-quality research and device development.

Teaching Experience 📚

In addition to her research, Ramadevi has taught practical sessions for both M.Sc. (Tech) Physics and B.Tech students. She has handled laboratory work, where she imparted valuable knowledge on experimental techniques and device characterization to budding scientists. This experience has helped her develop strong interpersonal and communication skills, which are essential for future academic and industrial collaborations.

Awards and Honors 🏆

Ramadevi’s excellence has been acknowledged through the Joint CSIR-UGC National Eligibility Test (NET) for Junior Research Fellowship (JRF) in 2017, where she secured an impressive All India Rank of 57. This achievement is a testament to her academic aptitude and research potential.

Legacy and Future Contributions 🌟

Looking forward, Ramadevi aims to make lasting contributions to the field of materials science and nanotechnology. Her research is poised to drive innovations in smart materials, sustainable technologies, and energy-efficient devices, with far-reaching implications for environmental sensing, smart window technologies, and optoelectronics. With her interdisciplinary approach and collaborative nature, she is well-positioned to make significant advancements in both academic and industrial research.

Publications Top Notes

Label-free detection of Aβ-42: a liquid crystal droplet approach for Alzheimer’s disease diagnosis

Authors: Saumya Ranjan Pradhan, Ramadevi Suguru Pathinti, Ramesh Kandimalla, Krishnakanth Chithari, Madhava Rao Veeramalla N., Jayalakshmi Vallamkondu
Journal: RSC Advances
Year: 2024

Enhanced ethanol gas detection using TiO2 nanorods dispersed in cholesteric liquid crystal: Synthesis, characterization, and sensing performance

Authors: Ramadevi Suguru Pathinti, Sunil Gavaskar Dasari, Buchaiah Gollapelli, Sreedevi Gogula, Ramana Reddy M.V., Jayalakshmi Vallamkondu
Journal: Journal of Alloys and Compounds
Year: 2024

Enhanced security through dye-doped cholesteric liquid crystal shells for anti-counterfeiting

Authors: Chris Mathew, Ramadevi Suguru Pathinti, Saumya Ranjan Pradhan, Buchaiah Gollapelli, Krishnakanth Chithari, Mrittika Ghosh, Ashok Nandam, Jayalakshmi Vallamkondu
Journal: Optical Materials
Year: 2024

ZnO nanoparticles dispersed cholesteric liquid crystal based smart window for energy saving application

Authors: Ramadevi Suguru Pathinti, Arun Kumar Tatipamula, Jayalakshmi Vallamkondu
Journal: Journal of Alloys and Compounds
Year: 2023

Energy saving, transparency changing thermochromism in dye-doped cholesteric liquid crystals for smart windows

Authors: Ramadevi Suguru Pathinti, Buchaiah Gollapelli, Saumya Ranjan Pradhan, Jayalakshmi Vallamkondu
Journal: Journal of Photochemistry and Photobiology A: Chemistry
Year: 2023

Song He | High energy physics | Best Researcher Award

Published on 12/03/202512/03/2025 by High Energy Physics

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.

Profile

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

Sanae ZRIOUEL | Computational Particle Physics | Women Researcher Award

Published on 12/03/2025 by High Energy Physics

Prof. Dr. Sanae ZRIOUEL | Computational Particle Physics | Women Researcher Award

Cadi Ayyad university | Morocco

Professor Dr. Sanae Zriouel is an esteemed Associate Professor of Physics at the Faculty of Sciences and Technology, Cadi Ayyad University in Marrakech, Morocco. With a deep passion for Mathematical Physics and cutting-edge research in nanomaterials, Dr. Zriouel has made significant contributions in various areas of condensed matter physics. Her academic journey spans multiple prestigious institutions in Morocco, and she has established herself as a key figure in the academic and scientific communities.

Profile

Early Academic Pursuits 📚

Dr. Zriouel’s journey began with a Bachelor’s degree in Physical Science from Ibn Tofail University, Morocco, followed by a Master’s degree in Mathematical Physics at Mohammed V University, Morocco. Her academic prowess was evident from early on, as she earned the highest distinctions in her Master’s and later in her PhD in Mathematical Physics from the same institution. She furthered her education with an Engineer’s degree in Electro-mechanics from ENSMR, Rabat, Morocco.

Professional Endeavors 🌍

Dr. Zriouel’s career in academia includes various teaching and research roles. She is currently an Associate Professor at Cadi Ayyad University, where she has been since 2022. Prior to this, she held positions as an Assistant Professor at Sultan Moulay Slimane University, Beni Mellal, and worked as a Dr. Researcher at Mohammed V University, where she developed a profound interest in nanomaterials and theoretical physics. Her roles are not limited to academia; she has been actively involved in multiple administrative responsibilities, serving as an elected member of university councils and commissions that contribute to the growth and development of scientific research and academic programs.

Contributions and Research Focus 🔬

Dr. Zriouel’s research interests include Graphene and related materials, the physics of 2D nanostructures, topological insulators, and chalcopyrite semiconductors. She has worked extensively on quantum dots, ab-initio calculations, and Monte Carlo simulations. Her work on spintronic properties, magnetocaloric effects, and the phase transitions of new materials has been instrumental in advancing our understanding of the physical properties of materials at the nano-scale. She has authored over 10 impactful scientific papers, contributing significant knowledge to materials science and theoretical physics.

Impact and Influence 🌟

Dr. Zriouel has had a far-reaching impact on both research and education. Her work has influenced various collaborations with institutions such as the Institut Néel, CNRS, Yildiz Technical University, and Abdus Salam International Centre for Theoretical Physics. Additionally, she has received recognition as a scientific visitor to prestigious institutions across the globe, including in Turkey, Italy, and France. Her leadership roles, including coordinating projects like the Extended African Network for Advanced 2D Materials, demonstrate her commitment to scientific collaboration and her efforts to foster an international exchange of ideas.

Academic Cites 📑

Dr. Zriouel’s research papers have been widely cited in the scientific community. Her work on half-metallic ferromagnetic properties, phase transitions in graphene, and DFT-based materials simulations has paved the way for significant advancements in spintronics and quantum materials. Notable publications include her contributions to Computational Condensed Matter and Modern Physics Letters. Her research continues to be cited globally, influencing the fields of nanotechnology, magnetism, and advanced materials.

Research Skills 🧠

Dr. Zriouel possesses a remarkable set of research skills that span theoretical physics and computational simulations. She is proficient in C++, Fortran, MATLAB, and other programming languages used for numerical simulations and ab-initio calculations. Her expertise includes tools like Quantum Espresso, LAMMPS, Wien2k, and SPRKKR, which she uses to explore the properties of advanced graphene-based materials, quantum dots, and other nanomaterials.

Teaching Experience 🎓

Dr. Zriouel is a dedicated educator, teaching a wide array of courses in physics at both the undergraduate and graduate levels. She teaches courses such as Quantum Mechanics, Electromagnetism, and Thermodynamics. Over the years, she has supervised more than 30 students, including Bachelor’s, Master’s, and PhD candidates. Her mentorship extends beyond coursework, as she is involved in guiding students in their research projects and helping them navigate the world of theoretical physics and computational modeling.

Awards and Honors 🏆

Dr. Zriouel has been recognized for her academic excellence with several prestigious awards. Notable honors include being awarded Full Membership of the Organization for Women in Science for the Developing World (OWSD) in 2020, and receiving the Award of Excellence from the National Center of Scientific Research of Morocco in 2014. In addition, she was the Valedictorian of both her Engineering program and her Physics graduate program. These accolades underline her exceptional academic achievements and her dedication to the advancement of science.

Legacy and Future Contributions 🔮

Dr. Zriouel’s legacy lies not only in her groundbreaking research but also in the impact she has had on the next generation of scientists. She has inspired and mentored numerous students, guiding them toward their own successful academic and research careers. Her contributions to the field of nanomaterials and quantum physics are set to influence future developments in green energy, quantum computing, and material science.

Publications Top Notes

In-depth study of double perovskite Sr₂NiTaO₆: Structural, electronic, thermoelectric, and spintronic properties for sustainable and high-performance applications

Authors: JU Ahsan, MR Rather, K Sultan, S Zriouel, E Hlil
Journal: Computational Condensed Matter
Year: 2025

Investigating thermodynamic and magnetic behavior of graphullerene-like nanostructure using Monte Carlo techniques

Authors: S Zriouel, A Mhirech, B Kabouchi, L Bahmad, Z Fadil, FM Husain
Journal: Philosophical Magazine
Year: 2025

Magnetic properties and magnetocaloric effects of the graphullerene-like 4-(Mg₄C) nanostructure: A Monte Carlo study

Authors: N Saber, S Zriouel, A Mhirech, B Kabouchi, L Bahmad, Z Fadil
Journal: Modern Physics Letters B
Year: 2024

Phase transitions and critical dielectric phenomena of janus transition metal oxides

Authors: S Zriouel
Journal: Materials Science and Engineering: B
Year: 2021

Effect of p–d hybridization on half metallic properties of some diluted II–IV–V₂ chalcopyrites for spintronic applications

Authors: S Zriouel, B Taychour, B Drissi
Journal: Physica Scripta
Year: 2020

Martin Birch | Interactions and fields | Best Researcher Award

Published on 12/03/202512/03/2025 by High Energy Physics

Dr. Martin Birch | Interactions and fields | Best Researcher Award

Senior Visiting Fellow at University of Central Lancashire | United Kingdom

Martin John Birch is a renowned Astrophysicist and Researcher with extensive experience in solar-terrestrial physics, geospace research, and fluid dynamics. With a career that spans several decades, Birch has made significant contributions to the scientific community through his research on solar particle events and earth’s magnetosphere. He currently holds the position of Senior Visiting Fellow in Solar-Terrestrial Physics at the Jeremiah Horrocks Institute for Mathematics, Physics, and Astronomy at the University of Central Lancashire.

Profile

Early Academic Pursuits 📚

Birch’s academic journey began in 1974 when he earned a BSc. (Hons) in Applied Physics from the University of Durham. His passion for research and space science led him to pursue a MPhil in 1993, followed by a MSc (by research) in Plasmaspheric Electron Content in 2000. In 2007, Birch achieved a PhD in solar particle events and their effects on geospace from the University of Central Lancashire, marking a significant milestone in his career.

Professional Endeavors 💼

Birch’s career spans a range of industries, including engineering, telecommunications, aerospace, and higher education. He initially worked as a Wireline Logging Engineer in Australia and later as a Microwave Research Engineer for Marconi Space and Defence Systems. His engineering expertise then led him to work in roles with British Aerospace, including as an Avionic Systems Engineer. Birch’s move into academia began in 1985, where he became a Senior Lecturer in Computing at Lancashire Polytechnic and continued in various academic positions at the University of Central Lancashire, contributing to research and teaching until 2007.

Contributions and Research Focus 🔬

Birch’s research focuses on the effects of solar particle events and solar wind streams on the Earth’s magnetosphere and ionosphere. His work has delved into complex phenomena such as coronal mass ejections and their impacts on space weather. His seminal book, “Effects of Solar Particle Events on Geospace”, published in 2010, underscores his expertise in space physics. Through his position as a Senior Visiting Fellow, he continues to push the boundaries of knowledge in solar-terrestrial physics, contributing valuable insights into the interaction between solar activity and Earth’s atmospheric layers.

Impact and Influence 🌍

Birch’s research has been instrumental in advancing our understanding of solar-terrestrial interactions, which has practical applications in space weather prediction, satellite communications, and nuclear industries. His work on high-speed solar wind and energetic solar protons has impacted the global scientific community. Birch’s academic publications, including over 20 journal papers, reflect his ability to influence the direction of astrophysics research, while his books and contributions to international conferences have cemented his reputation as a thought leader in the field.

Academic Citations 📑

Martin John Birch’s research has been widely cited across several academic papers, with his work on ionospheric electron content, solar particle events, and auroral activity gaining considerable attention. He has published extensively in journals like Radio Science, Annales Geophysicae, and the Journal of Geophysical Research. His contribution to the solar-terrestrial physics community is supported by a robust citation history, ensuring his research continues to inspire future generations of scientists.

Research Skills 🔧

Birch’s research skills span a variety of disciplines, including numerical modeling, data analysis, and space weather prediction. His expertise in real-time system design and computational fluid dynamics (CFD), especially in relation to the nuclear industry, showcases his versatility as a researcher. His ability to merge engineering principles with astrophysical concepts has led to breakthroughs in the study of solar particle interactions and space radiation.

Teaching Experience 🧑‍🏫

Birch’s academic career as a Senior Lecturer and Course Leader has seen him teach a wide range of subjects in Computing and Astrophysics. His teaching responsibilities included modules in system analysis, real-time systems, discrete mathematics, and industrial computing, where he shaped the education of many budding engineers and scientists. His leadership in creating and delivering undergraduate courses at the University of Central Lancashire and Lancashire Polytechnic demonstrates his dedication to academic excellence.

Awards and Honors 🏆

Throughout his career, Birch has received several honors that reflect his dedication to scientific advancement. His recognition as a Chartered Engineer and a Fellow of the Higher Education Academy highlights his professional standing. These prestigious awards and his ongoing contribution to space science solidify his position as a leading figure in the field.

Legacy and Future Contributions 🔮

Martin John Birch’s legacy lies in his pioneering research into space weather and its effects on Earth’s magnetosphere and ionosphere. His work has influenced both academic and industry sectors, particularly in space exploration and satellite technology. As a Senior Visiting Fellow, Birch is well-positioned to continue his groundbreaking research into the interactions between solar wind and the Earth’s atmosphere, with future contributions likely to focus on predicting space weather events and exploring new technological solutions to mitigate their impacts on global infrastructure.

Publications Top Notes

The dynamics of quasi-periodic ripples in the high-latitude F-region

Authors: Birch, M.J., Hargreaves, J.K.
Journal: Journal of Atmospheric and Solar-Terrestrial Physics
Year: 2021

Sunspot numbers and proton events in solar cycles 19 to 24

Authors: Birch, M.J., Bromage B.J.I.
Journal: Journal of Atmospheric and Solar-Terrestrial Physics
Year: May 2022

On the relation between coronal hole latitude range and the speed of the solar wind at Earth’s bowshock

Authors: Birch, M.J., Bromage B.J.I.
Journal: Phys Astron Int J
Year: 2023

A model to estimate energy deposition within the geomagnetosphere using Dst as a proxy for the Akasofu ε parameter

Authors: Birch, M.J.
Journal: Journal of Atmospheric and Solar-Terrestrial Physics
Year: Accepted for publication, February 2025

On the determination of the speed of a fast solar wind stream using two independent measurements of the interplanetary magnetic field

Authors: Birch, M.J.
Journal: Annals of Mathematics and Physics
Year: Accepted for publication, March 2025

Saeed Fakhry | Dark Matter Studies | Best Scholar Award

Published on 08/03/2025 by High Energy Physics

Dr. Saeed Fakhry | Dark Matter Studies | Best Scholar Award

Shahid Beheshti University | Iran

Saeed Fakhry is a postdoctoral researcher at Shahid Beheshti University specializing in theoretical physics, particularly in astrophysics, gravitation, and cosmology. His research interests span a range of topics, including numerical relativity, compact binary systems, dark sectors, and cosmological black holes. He is passionate about exploring the universe’s most fundamental questions and pushing the boundaries of theoretical research.

Profile

Early Academic Pursuits 🎓

Fakhry’s academic journey began with a BSc in Physics from Malayer University, where he worked on plasma chamber designs. This foundational experience led him to pursue graduate studies at Damghan University, earning an MSc in Astrophysics. His PhD at Shahid Beheshti University focused on Primordial Black Holes (PBHs), further sharpening his expertise in gravitational theory and cosmological observations.

Professional Endeavors 💼

Fakhry’s career in academia has seen him evolve from a Research Coordinator at K.N. Toosi University of Technology to his current postdoctoral position at Shahid Beheshti University. As a research associate, he’s dedicated to pushing forward the understanding of astrophysical phenomena, modified gravity, and cosmological models. His role also includes mentoring graduate students, fostering a community of intellectual curiosity and academic growth.

Contributions and Research Focus 🔬

Fakhry’s research focuses on cutting-edge theoretical astrophysics and cosmology. His work primarily investigates PBHs, dark matter interactions, and modified gravity theories. His research has redefined mass functions for dark matter halos and contributed new insights into gravitational wave signals. His contributions include examining neutron star mergers and the impact of dark matter on gravitational lensing. His published works in high-impact journals like The Astrophysical Journal and Physical Review D have made substantial impacts in both cosmology and gravitation.

Impact and Influence 🌍

Fakhry’s work has had a significant impact on both theoretical research and practical applications in astrophysics. By providing new frameworks for understanding early universe cosmology, dark matter interactions, and gravitational waves, his research is actively shaping future studies in these fields. His international collaborations and contributions to major research groups, including the Virgo Valencia Research Group, further enhance the global influence of his findings.

Academic Cites 📚

Fakhry’s work has been widely cited in the academic community, showcasing the importance of his contributions to astrophysics and cosmology. His research has garnered recognition for advancing theoretical physics and astrophysical observations, further emphasizing his influence within both the research community and global academic networks.

Research Skills 🔧

Fakhry possesses a strong analytical acumen and excels in problem-solving, particularly when tackling complex issues in cosmology and gravitation. His research skills also extend to modeling and simulating astrophysical phenomena using numerical relativity. His ability to bridge theoretical models with observational data from instruments like LIGO and Virgo underscores his proficiency in integrating theory with observation.

Teaching Experience 📖

Fakhry has taught advanced courses in General Relativity at the Master’s level, contributing to the academic growth of future physicists. He also actively mentors graduate students, guiding them in research on dark matter halos and PBHs. His role as a journal club organizer at Shahid Beheshti University fosters a collaborative environment where cutting-edge theoretical topics are discussed, promoting intellectual exchange within the academic community.

Awards and Honors 🏆

Fakhry has been honored with prestigious awards and scholarships throughout his academic career. These include the European Union Erasmus+ Mobility Grant, which allowed him to undertake research at the University of Valencia, and the Postdoctoral Grant from Shahid Beheshti University, which is enabling his current work. His recognition through these awards highlights his exceptional standing in the scientific community and his commitment to advancing knowledge.

Legacy and Future Contributions 🌟

Fakhry’s legacy is built on a foundation of innovative research and academic leadership. His future contributions are poised to drive theoretical astrophysics and cosmology into new realms, particularly in understanding dark matter and gravitational waves. His focus remains on pushing the boundaries of knowledge in these areas while mentoring the next generation of scientists. Fakhry’s continued work is expected to shape the future of theoretical physics, especially in the context of modified gravity and the cosmological challenges of the early universe.

Publications Top Notes

Compact Binary Merger Rate with Modified Gravity in Dark Matter Spikes

Authors: Saeed Fakhry, Sara Gholamhoseinian, Marzieh Farhang
Journal: The Astrophysical Journal
Year: 2024

Primordial Black Hole–Neutron Star Merger Rate in Modified Gravity

Authors: Saeed Fakhry, Maryam Shiravand, Marzieh Farhang
Journal: The Astrophysical Journal
Year: 2024

Primordial Black Hole Merger Rate in f(R) Gravity

Authors: Saeed Fakhry
Journal: The Astrophysical Journal
Year: 2024

Compact Binary Merger Rate in Dark-matter Spikes

Authors: Saeed Fakhry, Zahra Salehnia, Azin Shirmohammadi, Mina Ghodsi Yengejeh, Javad T. Firouzjaee
Journal: The Astrophysical Journal
Year: 2023

Effect of a High-precision Semianalytical Mass Function on the Merger Rate of Primordial Black Holes in Dark Matter Halos

Authors: Saeed Fakhry, Antonino Del Popolo
Journal: Physical Review D
Year: 2023

Bhakti Pada Das | Experimental methods | Best Researcher Award

Published on 08/03/2025 by High Energy Physics

Dr. Bhakti Pada Das | Experimental methods | Best Researcher Award

Ex-Student, Indian Institute of Technology, Kharagpur | India

Dr. Bhakti Pada Das is a distinguished physicist with expertise in the structural, dielectric, electrical, and magnetic properties of various materials. He completed his B.Sc. (Honours) in Physics from Calcutta University in 1981, followed by his M.Sc. in Physics from IIT Kharagpur in 1984. He earned his Ph.D. in Physics from Vidyasagar University, Midnapore in 2006. With over three decades of academic and research experience, Dr. Das has made significant contributions to material science, particularly in ferroelectric systems and nanotechnology.

Profile

Early Academic Pursuits 🎓

Dr. Das began his academic journey at Calcutta University, where he obtained his B.Sc. in Physics (Honours), followed by an advanced M.Sc. from IIT Kharagpur, India. His academic interests during this time laid the foundation for his doctoral work. He pursued his Ph.D. research at Vidyasagar University, which focused on the structural, dielectric, and electrical properties of rare-earth-modified Pb(SnTi)O3 ferroelectric systems. This research work set the stage for his later contributions in material science.

Professional Endeavors 🔬

Dr. Das has worked on various significant research projects throughout his career. His expertise spans areas such as dilute magnetic semiconductors, nanofluid technology, and satellite communication. Notably, his work in Ka band propagation experiments at the Indian Institute of Technology, Kharagpur, aimed at improving satellite communication in tropical regions, showcased his innovative approach to solving real-world problems. Additionally, his hands-on experience with the development of NdFeB-based magnets further highlights his comprehensive skill set in experimental physics.

Contributions and Research Focus 🧠

Dr. Das’s research focus includes the study of ferroelectric materials, dilute magnetic semiconductors (DMS), magnetic nanofluids, and the thermal properties of materials. His research on Pb(SnTi)O3 ceramics, In2O3-based DMS, and Sm-Co nanoparticles offers in-depth insights into the electrical and magnetic properties of these materials, crucial for modern electronics and nanotechnology. His work on the thermal conductivity of magnetic nanofluids has also led to advancements in the field of heat transfer and energy efficiency.

Impact and Influence 🌍

Dr. Das’s work has had a significant impact on the fields of material science and nanotechnology. His publications in high-impact journals like Materials Science and Engineering: B, Journal of Electronic Materials, and Journal of Thermal Analysis and Calorimetry have influenced future research in ferroelectric materials, magnetic semiconductors, and thermal management systems. His innovative research techniques and contributions are being widely cited, contributing to the growth of nanotechnology and its real-world applications.

Academic Citations 📖

Dr. Bhakti Pada Das has been widely cited in academic literature, particularly in the fields of ferroelectric materials and nanomaterials. With a diverse publication record, his research has garnered attention in leading scientific journals, making him a recognized scholar in material science. His most recent work on Fe-doped In2O3 nanoparticles in Materials Science and Engineering: B is one of his most cited articles, reflecting his influence in advancing knowledge in the domain of magnetic semiconductors.

Research Skills 🛠️

Dr. Das possesses a vast skill set in material preparation techniques, such as solid-state reaction methods, sol-gel processes, and arc melting & melt spinning for alloy preparation. His expertise in structural analysis using XRD (X-ray diffraction) and SEM (Scanning Electron Microscopy) enables him to conduct high-level material characterization. Additionally, he is proficient in magnetic and electrical property studies, particularly for dilute magnetic semiconductors and ferroelectric ceramics.

Teaching Experience 👨‍🏫

As an academic mentor, Dr. Das has taught a wide range of undergraduate and postgraduate courses in physics, particularly in materials science. His experience in guiding students through complex experimental setups and theoretical concepts makes him an outstanding educator. His ability to translate his advanced research knowledge into accessible teachings has inspired many future scientists and researchers.

Legacy and Future Contributions 🌱

Dr. Das’s legacy lies in his dedication to advancing knowledge in the field of material science. He is expected to continue contributing to the study of novel materials, particularly in nanotechnology and energy-efficient systems. His future research may focus on emerging fields like quantum materials and nanoelectronics, areas where his experience in dilute magnetic semiconductors and ferroelectric materials can be applied to push the boundaries of modern technology. Dr. Das’s continued work will undoubtedly impact both academic research and real-world applications, contributing to the development of sustainable technologies and cutting-edge materials that can shape the future of electronics, communication, and energy systems.

Publications Top Notes

Structural, magnetic and optical characterization of 5 atomic % Fe doped In2O3 dilute magnetic semiconducting nanoparticles

Authors: Bhakti Pada Das, Tapan Kumar Nath, Sourav Mandal, Ashes Shit, Palash Nandi, Subhasis Shit, Bishnu Chakraborty, Panchanan Pramanik
Journal: Materials Science and Engineering: B
Year: 2025

Magnetic and Optical Properties of Dilute Magnetic Semiconducting (In0.9Mn0.1)2O3 Nanoparticles

Authors: Bhakti Pada Das, Tapan Kumar Nath, Sourav Mandal, Ashes Shit, Bishnu Chakraborty, Subhasis Shit, Sananda Das, Palash Nandi, Panchanan Pramanik
Journal: Journal of Electronic Materials
Year: 2023

Structural, Microstructural, and Electrical Properties Study of Pb(Sn0.45Ti0.55)O3 Ceramics

Authors: Bhakti Pada Das, Bhabani Sankar Patnaik, Tanmaya Jena, Sailabhama Nayak, Geetanjali Nayak, Krishnamayee Bhoi, Uttam Sahu, Prasanta Kumar Mahapatra, Ram Naresh Prasad Choudhary, Subrata Karmakar, Hari Sankar Mohanty
Journal: ECS Journal of Solid State Science and Technology
Year: 2024

Room temperature ferromagnetism in chemically synthesized dilute magnetic semiconducting (In0.95Mn0.05)2O3 nanoparticles

Authors: Bhakti Pada Das, Akash Oraon, Tapan Kumar Nath, Tapasendra Adhikary, Shampa Aich, Panchanan Pramanik
Journal: Journal of Materials Science: Materials in Electronics
Year: 2020

Impact of magnetic field on the thermal properties of chemically synthesized Sm-Co nanoparticles based silicone oil nanofluids

Authors: Akash Oraon, Bhakti Pada Das, Monisha Michael, Tapasendra Adhikary, Purbarun Dhar, Shampa Aich, Sudipto Ghosh
Journal: Journal of Thermal Analysis and Calorimetry
Year: 2021

Jianwen Yang | Experimental methods | Best Researcher Award

Published on 08/03/2025 by High Energy Physics

Assoc. Prof. Dr. Jianwen Yang | Experimental methods | Best Researcher Award

Associate Professor, Master’s Supervisor, Deputy Head of the Physics Department at Shanghai Normal University | China

Dr. Jianwen Yang is an Associate Professor at Shanghai Normal University, holding a Ph.D. in Physical Electronics from Fudan University. His primary research focus lies in oxide semiconductors and information display technologies. With significant experience in addressing instability issues in industrial devices, he has contributed to analyzing the performance of a-IGZO TFTs in companies like TSMC and AUOtronics. His innovative work in n-type tin oxide-based TFTs and indium-free doped tin oxide-based TFTs has led to breakthroughs in the field, providing devices with superior electrical characteristics.

Profile

Early Academic Pursuits 📚

Dr. Yang’s academic journey began with a solid foundation in Physical Electronics, completing his Ph.D. at Fudan University. During his early studies, he developed a keen interest in the intersection of material science and electronics, which led him to explore oxide thin-film transistors (TFTs) as a promising avenue for future advancements. His focus on new materials and material simplification laid the groundwork for his later innovations in tin oxide-based TFTs, a critical area in the development of modern information display technologies.

Professional Endeavors 💼

Dr. Yang’s professional career has been marked by collaborations with prominent industry leaders like TSMC and AUOtronics, where he contributed to solving the instability challenges in industrialized a-IGZO TFTs. These efforts have provided valuable insights into the performance optimization of thin-film transistors, further driving the industry forward. His participation in national projects, such as those funded by the National Natural Science Foundation of China (NSFC), also highlights his commitment to advancing the field through both academic research and real-world applications.

Contributions and Research Focus 🔬

Dr. Yang’s pioneering research in n-type tin oxide-based TFTs led to the introduction of novel indium-free doped tin oxide materials like SnWO, SnSiO, and SnNiO, which have all exhibited superior electrical characteristics. His work on comparing top/bottom-gate a-IGZO TFTs under varying stress conditions provided valuable insights into threshold voltage shifts and carrier concentration variations, significantly impacting the design and stability of oxide semiconductors in practical applications. He has consistently pushed the boundaries of material research, particularly in the flexible electronics sector.

Impact and Influence 🌍

Dr. Yang’s groundbreaking research has had a profound impact on the development of oxide semiconductor devices, particularly in TFT technology. His innovative approaches have been cited in multiple review articles, and his work continues to influence both academic researchers and industry practitioners. His research on indium-free tin oxide-based TFTs has not only enriched academic literature but also paved the way for more sustainable and efficient solutions in the information display industry. The superior electrical characteristics of his materials have positioned them as viable alternatives to traditional indium-based materials, which are costly and scarce.

Academic Cites 📈

Dr. Yang has published over 38 journals in top-tier scientific databases, including SCI and Scopus, with his work receiving 11 citations. His innovative research has been referenced in numerous review articles, further establishing him as a thought leader in his field. These citations reflect the widespread recognition of his research’s significance, and his publications continue to influence the academic community’s understanding of oxide semiconductors and TFT stability.

Research Skills 🛠️

Dr. Yang’s research skills span a wide range of disciplines, from material science to electronic device engineering. His expertise in thin-film transistor design, instability analysis, and new material development has allowed him to push the envelope in semiconductor research. He is particularly skilled in analyzing the electrical performance of TFTs under various stress conditions, demonstrating an acute understanding of the intricate relationship between material properties and device functionality. Additionally, his work in flexible electronics is a testament to his ability to innovate in emerging areas.

Teaching Experience 👩‍🏫

As an Associate Professor at Shanghai Normal University, Dr. Yang has been involved in educating and mentoring the next generation of scientists and engineers. He brings his extensive research experience into the classroom, enriching students’ learning experiences. Dr. Yang’s teaching focuses on semiconductor physics, material science, and electronics. His dedication to student development is evident in his guidance of graduate students and the collaborative environment he fosters for academic exploration.

Awards and Honors 🏅

Dr. Yang’s contributions have been recognized by several prestigious national research organizations, including the National Natural Science Foundation of China. His research projects, such as the Study on the Instability of Flexible Amorphous SnSiO Thin Film Transistors, have earned him respect in the academic community and have helped elevate Shanghai Normal University‘s status in the field of electronic materials research.

Legacy and Future Contributions 🔮

Dr. Yang’s research legacy lies in his innovative contributions to oxide semiconductor technology and his dedication to finding sustainable solutions for the electronics industry. His ongoing research projects, including his work on the 345GHz Submillimeter Wave Sideband Separation Receiver for LCT Telescope, show his commitment to exploring cutting-edge technologies. Moving forward, Dr. Yang plans to continue refining indium-free tin oxide-based TFTs and explore their industrial scalability. His work has the potential to impact a variety of industries, from flexible displays to advanced sensors, shaping the future of electronic materials.

Publications Top Notes

Exploring soil-buoyancy interactions: experimental designs and educational implications for enhancing students’ scientific inquiry skills

Authors: Zijian Gu, Jianwen Yang
Journal: Physics Education
Year: 2025

Fast-response IWO/Si heterojunction photodetectors

Authors: Xiaochuang Dai, Jianwen Yang, Huishan Wang, Yunxi Luo, Jinying Zeng, Wangzhou Shi, Feng Liu
Journal: Journal of Physics D: Applied Physics
Year: 2025

Enhancement of electrical characteristics of SnGaO thin-film transistors via argon and oxygen plasma treatment

Authors: Yinli Lu, Xiaochuang Dai, Jianwen Yang, Ying Liu, Duo Cao, Fangting Lin, Feng Liu
Journal: Vacuum
Year: 2024

Preparation of chalcogenide perovskite SrHfS3 and luminescent SrHfS3:Eu2+ thin films

Authors: Yanbing Han, Jiao Fang, Yurun Liang, Han Gao, Jianwen Yang, Xu Chen, Yifang Yuan, Zhifeng Shi
Journal: Applied Physics Letters
Year: 2024

Degradation Behavior of Etch-Stopper-Layer Structured a-InGaZnO Thin-Film Transistors Under Hot-Carrier Stress and Illumination

Authors: Dong Lin, Wan-Ching Su, Ting-Chang Chang, Hong-Chih Chen, Yu-Fa Tu, Kuan-Ju Zhou, Yang-Hao Hung, Jianwen Yang, I-Nien Lu, Tsung-Ming Tsai et al.
Journal: IEEE Transactions on Electron Devices
Year: 2021

Shun-Jia Huang | Gravitational Waves | Best Researcher Award

Published on 06/03/202506/03/2025 by High Energy Physics

Dr. Shun-Jia Huang | Gravitational Waves | Best Researcher Award

Postdoctor at Sun Yat-sen University | China

Shun-Jia Huang is an accomplished PhD candidate in Theoretical Physics at Sun Yat-sen University, China, with an academic background that includes a Master’s degree and Bachelor’s degree from the same institution. His research focuses primarily on gravitational waves (GW), multi-messenger astronomy, and their applications in cosmology. Currently, he is a postdoctoral researcher at the same university, continuing his cutting-edge work in these fields.

Profile