Author: AMO Physics

🎓 Early Academic Pursuits

Prof. Teiji Nishio embarked on an exceptional academic journey, earning degrees in both physics and medicine. He obtained his Ph.D. in Physics from Rikkyo University in 1997 and later pursued a Ph.D. in Medicine from the University of Tokyo in 2011. His interdisciplinary background in physics and medicine laid the foundation for his groundbreaking research in medical physics, specifically in radiation therapy and particle therapy. His academic journey through prestigious institutions such as Rikkyo University and the University of Tokyo has provided him with an unparalleled depth of expertise in both theoretical and applied aspects of medical physics.

💼 Professional Endeavors

Prof. Nishio has held prestigious positions across leading Japanese universities and research institutions. Currently, he serves as a Professor at Osaka University’s Graduate School of Medicine, Division of Health Science, in the Medical Physics Laboratory (2021-Present). Before this, he was a Professor at Tokyo Women’s Medical University (2016-2020), contributing significantly to the advancement of medical physics education and research. His earlier career at the National Cancer Center (1998-2015) saw him lead the Particle Therapy Division, where he played a key role in the development and implementation of innovative cancer treatments. His diverse employment history also includes positions at Hiroshima University, Kyoto University, and Kitasato University, further solidifying his reputation as a leading expert in his field.

🔬 Contributions and Research Focus

Prof. Nishio’s research is centered around medical physics, with a particular focus on radiation oncology, particle therapy, and accelerator physics. His work has contributed significantly to advancements in cancer treatment through innovative radiation therapy techniques. His tenure at the National Cancer Center saw the development of state-of-the-art particle therapy techniques, improving the precision and effectiveness of radiation treatments for cancer patients. His expertise in accelerator physics and medical imaging has also led to improvements in radiation safety and treatment efficacy.

🌍 Impact and Influence

Prof. Nishio's impact extends beyond research; he has played a vital role in shaping the next generation of medical physicists through his extensive teaching and mentorship. His contributions to medical physics are widely recognized, making him a sought-after visiting professor at multiple institutions, including Tokyo Women’s Medical University, Hiroshima University, Kyoto University, Tokyo University of Science, and Rikkyo University. His influence is evident through the successful careers of numerous researchers and clinicians who have been mentored under his guidance.

🏆Academic Cites

With a career spanning over two decades, Prof. Nishio's research has been extensively cited in high-impact journals related to medical physics, radiation therapy, and oncology. His pioneering work in particle therapy and radiation oncology has become a cornerstone for ongoing advancements in cancer treatment. His published works have been referenced in major international studies, demonstrating the profound impact of his research on the global medical community.

🌟 Legacy and Future Contributions

Prof. Nishio’s legacy is defined by his relentless pursuit of excellence in medical physics. His future contributions are expected to further revolutionize cancer treatment, particularly through the continued enhancement of particle therapy and radiation oncology techniques. As a leader in the field, he remains committed to fostering innovation, mentoring young scientists, and pushing the boundaries of medical physics to improve patient outcomes. His research and leadership ensure that his contributions will leave a lasting mark on the world of medicine and physics alike.

📝Notable Publication

📝Clinical workload profile of medical physics professionals at particle therapy centers: A National Survey in Japan

Authors: S. Ota (Seiichi), K. Yasui (Keisuke), T. Ogata (Toshiyuki), T. Kojima (Toru), H. Onishi (Hiroshi)

Journal: Journal of Radiation Research

Year: 2025

Citations: 0

📝Effects of institutional experience on plan quality in stereotactic radiotherapy using HyperArc for brain metastases

Authors: S. Kihara (Sayaka), S. Ohira (Shingo), N. Kanayama (Naoyuki), T. Nishio (Teiji), K. Konishi (Koji)

Journal: In Vivo

Year: 2025

Citations: 0

📝Diffusion equation quantification: Selective enhancement algorithm for bone metastasis lesions in CT images

Authors: Y. Anetai (Yusuke), K. Doi (Kentaro), H. Takegawa (Hideki), M. Nakamura (Mitsuhiro), S. Nakamura (Satoaki)

Journal: Physics in Medicine and Biology

Year: 2024

Citations: 0

📝A novel internal target volume definition based on velocity and time of respiratory target motion for external beam radiotherapy

Authors: M. Yamanaka (Masashi), T. Nishio (Teiji), K. Iwabuchi (Kohei), H. Nagata (Hironori)

Journal: Radiological Physics and Technology

Year: 2024

Citations: 0

📝Preliminary study of luminescence phenomena from various materials under ultra-high dose rate proton beam irradiation for dose management

Authors: R. Yamada (Ryosaku), T. Nishio (Teiji), D. Kinkawa (Daiki), H. Yoshimura (Hitoshi), J. Kataoka (Jun)

Journal: Scientific Reports

Year: 2024

Citations: 0

📝Assessing tumor volumetric reduction with consideration for setup errors based on mathematical tumor model and microdosimetric kinetic model in single-isocenter VMAT for brain metastases

Authors: H. Nakano (Hisashi), T. Shiinoki (Takehiro), S. Tanabe (Satoshi), T. Nishio (Teiji), H. Ishikawa (Hiroyuki)

Journal: Physical and Engineering Sciences in Medicine

Year: 2024

Citations: 0

📝Scintillation of polyester fabric and clothing via proton irradiation and its utilization in surface imaging of proton pencil beams

Authors: S. Yamamoto (Seiichi), T. Yamashita (Tomohiro), M. Yoshino (Masao), T. Nishio (Teiji), J. Kataoka (Jun)

Journal: Scientific Reports

Year: 2024

Citations: 0

Changkun Ma – Dam-broken Debris Flow – Best Researcher Award

Posted on 07/02/202507/02/2025 by AMO Physics

Assist. Prof. Dr. Changkun Ma - Dam-broken Debris Flow - Best Researcher Award

Institute of Rock and Soil Mechanics, Chinese Academy of Sciences - China

Author Profile

🎓 Early Academic Pursuits

Assist. Prof. Dr. Changkun Ma embarked on his academic journey in Civil Engineering at China Three Gorges University, where he earned his bachelor's degree in 2016. His passion for geotechnical engineering led him to pursue both his master's and PhD at the University of Chinese Academy of Sciences from 2016 to 2022. During this period, he focused on advanced geotechnical studies, laying a solid foundation for his expertise in soil mechanics, tailings behavior, and disaster mitigation strategies.

💼 Professional Endeavors

Since July 2022, Dr. Changkun Ma has been an Assistant Researcher at the State Key Laboratory of Geotechnical Mechanics and Engineering within the Institute of Rock and Soil Mechanics, Chinese Academy of Sciences. His work in this esteemed institution involves high-impact research on soil behavior, rock mechanics, and disaster prevention, particularly related to dam-broken debris flow and its devastating consequences. His professional contributions extend to several patents and innovative experimental methodologies in geotechnical engineering.

🔬 Contributions and Research Focus

Dr. Changkun Ma has made significant contributions to geotechnical engineering, with a strong emphasis on dam-broken debris flow and soil stability. His research delves into nonlinear modeling of fine tailings using fractal theory and particle flow methods, crucial for understanding the failure mechanisms in tailings dams. His work also includes the development of high-stress osmometer devices, seepage consolidation soil sample preparation tools, and in-situ erosion rate measuring instruments. His patents reflect his dedication to advancing experimental geomechanics and field instrumentation for real-world applications.

🌍 Impact and Influence

Dr. Ma's work has had a profound impact on both academic and industrial sectors. His research on dam-broken debris flow is instrumental in improving risk assessment and mitigation strategies for tailings storage facilities and geohazard-prone regions. His collaboration with leading experts and participation in national projects further underscore his influence in shaping the future of geotechnical engineering. His patented innovations are widely used in research and industry, contributing to safer and more sustainable engineering practices.

🏆Academic Cites

Dr. Ma’s contributions have been recognized through multiple citations in geotechnical and civil engineering literature. His research has been cited in studies related to tailings behavior, soil mechanics, and disaster prevention. His involvement in the National Natural Science Foundation of China and his participation in key research projects highlight the significance of his work in understanding dam-broken debris flow and its geotechnical implications.

🌟 Legacy and Future Contributions

As a dedicated researcher and innovator, Dr. Changkun Ma is committed to expanding the frontiers of geotechnical engineering. His future contributions will focus on refining numerical modeling techniques, enhancing soil stability assessment methods, and developing next-generation geotechnical devices. His legacy lies in his pioneering work on dam-broken debris flow, which will continue to shape disaster mitigation strategies and infrastructure safety measures for years to come.

📝Notable Publication

📝Study on the Microstructure and Permeability Characteristics of Tailings Based on CT Scanning Technology

Authors: Li, Qiyang; Ma, Changkun; Zhang, Chao; Guo, Yongcheng; Zhou, Tong

Journal: Applied Sciences (Switzerland)

Year: 2024

Citations: 0

📝Evolution of Microscopic Pore Structure and Deterioration Mechanism of Sandstone Subjected to Freeze-Thaw Cycles

Authors: Zhang, Junyue; Wang, Guibin; Ma, Changkun; Liu, Huandui; Yang, Mengmeng

Journal: Bulletin of Engineering Geology and the Environment

Year: 2024

Citations: 0

Nikolai Lavrik – Nature of Hydrogen Bonding – Molecular Physics Achievement Award

Posted on 07/02/202507/02/2025 by AMO Physics

Prof. Nikolai Lavrik - Nature of Hydrogen Bonding - Molecular Physics Achievement Award

Institute of Chemical Kinetics&Combustion, Sibirian Branch, Russian Academy of Sciences - Russia

Author Profile

🎓 Early Academic Pursuits

Prof. Nikolai Lavrik’s academic journey began with a strong foundation in physical chemistry and molecular interactions, which later shaped his expertise in hydrogen bonding and quantum-chemical calculations. His early pursuits were marked by a keen interest in spectroscopy and theoretical chemistry, leading him to explore the nature of hydrogen bonding through experimental and computational techniques.

💼 Professional Endeavors

Prof. Lavrik has made significant contributions to molecular chemistry, particularly in the study of hydrogen bonding interactions. His work spans infrared (IR) spectroscopy and density functional theory (DFT) calculations, offering a deeper understanding of molecular interactions. His research on the nature of hydrogen bonding has provided critical insights into how solvent molecules influence charge distributions in organic compounds, which has broad implications for chemical and biological sciences.

🔬 Contributions and Research Focus

Prof. Lavrik’s research focuses on the estimation of electrostatic and covalent contributions to the enthalpy of hydrogen bond formation, as demonstrated in his studies published in leading journals. His articles explore H-complexes with proton-acceptor molecules, revealing how electronic properties of side charges in neutral solvents impact nitrogen and hydrogen atoms in carbazole molecules. His studies in the nature of hydrogen bonding provide a fundamental understanding of molecular interactions, benefiting fields such as material science, pharmaceuticals, and bioengineering.

🌍 Impact and Influence

Despite his recent publications not yet being widely cited, Prof. Lavrik’s research holds significant value for the scientific community. His contributions to hydrogen bonding analysis, particularly using IR spectroscopy and quantum-chemical methods, have established a foundation for future studies in molecular dynamics. His findings regarding spectral shifts in erythrocyte oxyhemoglobin interactions with organic molecules have potential applications in biomedical sciences.

🏆Academic Cites

Although his recent works have not accumulated citations, their importance lies in their pioneering approach to studying hydrogen bonding mechanisms. His research in the nature of hydrogen bonding offers essential data for scientists investigating molecular interactions, structural stability, and chemical reactivity. His work is expected to gain recognition as researchers continue building upon his theoretical and experimental findings.

🌟 Legacy and Future Contributions

Prof. Nikolai Lavrik’s legacy is rooted in his methodical approach to understanding hydrogen bonding and molecular interactions. His future contributions will likely enhance the predictive models of chemical bonding, enabling better material design and drug formulation. As he continues his research, his work will remain a cornerstone for those studying the nature of hydrogen bonding, further influencing chemical and physical sciences.

📝Nature of Hydrogen Bonding

Prof. Nikolai Lavrik’s extensive research on the nature of hydrogen bonding explores electrostatic and covalent contributions to molecular interactions. His work provides new insights into the nature of hydrogen bonding, particularly through IR spectroscopy and DFT calculations. The significance of the nature of hydrogen bonding in chemistry, biology, and material science continues to be a driving force in his research endeavors.

Notable Publication

📝Effect of the electronic properties of the side charges of neutral solvent molecules on the charges of the N and H atoms of the carbazole molecule: IR experiment and DFT calculations

Authors: M.K. Khodiev, I. Noureddine Issaoui, O.M. Al-Dossary, N.L. Lavrik

Journal: Journal of Molecular Liquids

Year: 2024

Citations: 0

📝Estimation of electrostatic and covalent contributions to the enthalpy of H-bond formation in H-complexes of 1,2,3-benzotriazole with proton-acceptor molecules by IR spectroscopy and DFT calculations

Authors: M.K. Khodiev, U. Holikulov, I. Noureddine Issaoui, L.G. Bousiakoug, N.L. Lavrik

Journal: Journal of King Saud University - Science

Year: 2023

Citations: 0

📝Imidazole H-Complexes with Proton-Acceptor Molecules from the Data of IR Spectroscopy and Quantum-Chemical Calculations

Authors: N.U. Mulloev, N.A. Majidov, N.L. Lavrik

Journal: Russian Physics Journal

Year: 2022

Citations: 0

📝On the Nature of the Spectral Shift of the Soret Band of Erythrocyte Oxyhemoglobin when Organic Molecules Are Added to an Erythrocyte Suspension

Authors: N.L. Lavrik

Journal: Biophysics

Year: 2022

Citations: 0

Ali Idriss – Radiation Protection and Radiation Dosimetry – Best Researcher Award

Posted on 07/02/202507/02/2025 by AMO Physics

Mr. Ali Idriss - Radiation Protection and Radiation Dosimetry - Best Researcher Award

Universiti Sains Malaysia - Malaysia

Author Profile

🎓 Early Academic Pursuits

Mr. Ali Idriss began his academic journey with a Bachelor’s Degree in Physics from the University of Sebha, Libya (2005), where he developed a strong foundation in fundamental physics and its applications. His passion for radiation protection and radiation dosimetry led him to pursue a Master's Degree in Radiation Science at Universiti Sains Malaysia (USM) in 2017. His graduate studies allowed him to specialize in radiation science, focusing on advanced dosimetric techniques and their implications for safety in medical and industrial applications.

💼 Professional Endeavors

Mr. Ali Idriss is currently a PhD student in Medical Physics at Universiti Sains Malaysia (2021-2025), specializing in radiation dosimetry. Alongside his academic pursuits, he has actively contributed to the education sector as a Lecturer at the Higher Institute of Science and Technology, Tamzawa Al-Shati, Libya. His role as an educator has enabled him to train future scientists in the principles of radiation protection and radiation dosimetry, ensuring that emerging professionals are well-versed in radiation safety protocols and measurement techniques.

🔬 Contributions and Research Focus

Mr. Idriss’s research primarily focuses on radiation dosimetry, particularly the thermoluminescence properties of multilayer thin films for accurate radiation measurement. His significant contributions include studies on TiO2/Cu/TiO2 multilayer thin films and their dosimetric properties under gamma-ray exposure. His work has been recognized in high-impact journals, including the Journal of Luminescence, where he has published pioneering research on the thermoluminescence properties of nanomaterials for radiation detection. His research explores the effect of annealing temperature on dosimetric properties, contributing to the development of more efficient and reliable radiation detectors.

🌍 Impact and Influence

Mr. Idriss’s work has had a profound impact on the field of radiation protection and radiation dosimetry. His contributions provide essential insights into the improvement of radiation dosimeters, which are critical for ensuring safety in medical, industrial, and nuclear applications. His innovative research has led to the development of advanced materials for radiation detection, improving measurement accuracy and reliability. His recognition as a Patent Winner & Silver Medalist at the Innozilla Science, Technology & Innovation Exhibition in Malaysia (2024) further solidifies his influence in the scientific community.

🏆Academic Cites

His research publications have gained significant attention, with citations from various scholars working on radiation dosimetry and thin-film technologies. His work serves as a crucial reference for researchers aiming to enhance thermoluminescent dosimeters for medical and industrial radiation monitoring. His collaboration with leading researchers has expanded the applications of his findings, reinforcing the importance of his contributions to radiation measurement science.

🌟 Legacy and Future Contributions

Mr. Ali Idriss’s legacy in radiation protection and radiation dosimetry is defined by his dedication to advancing radiation detection technologies. His future contributions will likely focus on improving thermoluminescent materials for higher sensitivity and stability, further enhancing the precision of radiation monitoring systems. As a PhD candidate, he continues to push the boundaries of radiation dosimetry, ensuring that his research leads to practical applications in medical imaging, nuclear safety, and environmental radiation monitoring. His work is expected to have lasting implications for both academia and industry, making a significant contribution to the field of radiation science.

📝Radiation Protection and Radiation Dosimetry

Mr. Ali Idriss's research in radiation dosimetry has played a pivotal role in enhancing the accuracy and effectiveness of radiation measurement techniques. His work in radiation protection and radiation dosimetry ensures that exposure to ionizing radiation is carefully monitored and controlled, benefiting medical, industrial, and environmental sectors. Through his innovative contributions to radiation dosimetry, Mr. Idriss is helping to advance safety protocols and measurement accuracy for future applications.

Notable Publication

📝Thermoluminescence properties of TiO₂/Cu/TiO₂ multilayer thin films fabricated by (RF/DC) sputtering for radiation dosimetry

Authors: ASA Idriss, NNAN Ab Razak, NM Ahmed, YA Abdulla

Journal: Journal of Luminescence

Year: 2023

Citations: 7

📝Synthesis, and impact of GaN deposition on the physical, optical, and structural properties of Nd³⁺-doped Na₂O borate glasses prepared with soda lime (SLS) glass as a silica source

Authors: NS Ezra, IS Mustafa, MI Sayyed, KK Dakok, IM Fadhirul, TH Khazaalah, ...

Journal: Optical Materials

Year: 2024

Citations: 3

📝Synthesis and Effect of MgSO₄ co-doping on the Optical, IR, and Raman Spectroscopic Studies of Eu³⁺-Doped Alkaline Silica Borate Glasses Produced with SLS

Authors: NS Ezra, IS Mustafa, MI Sayyed, KK Dakok, TH Khazaalah, GI Efenji, ...

Journal: Silicon

Year: 2024

📝Thermoluminescence Radiation Dosimetry in TiO₂/Cu/TiO₂ Multilayer Structures Exposed to Gamma-Ray Irradiation

Authors: A Idriss, NNA Nik Ab Razak, N Ahmed, Y Abdulla

Journal: Naseer and Abdulla, Youssef, Thermoluminescence Radiation Dosimetry in TiO₂

Year: Not specified

📝Characteristics and Dosimetric Properties of Tissue-Equivalent Thermoluminescent Glass Detector Based on Al-Li-Zn, Borate Oxide Dope Dy³⁺

Authors: GI Efenji, ISB Mustapha, NN Yusof, RJ Anthony, FA Kamgba, U PO, ...

Journal: Science and Technology Indonesia

Year: Not specified

Feng Qiu – Optoelectronic Materials and Novel Devices – Best Researcher Award

Posted on 06/02/202506/02/2025 by AMO Physics

Prof. Feng Qiu - Optoelectronic Materials and Novel Devices - Best Researcher Award

Yunnan University - China

Author Profile

🎓 Early Academic Pursuits

Prof. Feng Qiu began his academic journey with a focus on material science, enrolling in Yunnan University and later the Chinese Academy of Sciences, where he obtained his PhD. During his early academic years, Prof. Qiu demonstrated a strong aptitude for understanding the structure and properties of materials, which laid the foundation for his future research in optoelectronic materials. His undergraduate studies at various prestigious institutions like the University of Science and Technology of China and Kunming Institute of Physics further solidified his understanding and passion for optoelectronic materials and device fabrication.

💼 Professional Endeavors

Prof. Feng Qiu is currently an Associate Researcher at Yunnan University, where he has established himself as a leader in the field of optoelectronic materials. As the Deputy Technical Director of Yunnan Lincang Xinyuan Germanium Industry Co., Ltd, Prof. Qiu bridges the gap between academia and industry, applying his research to real-world applications. He leads the 2D-X group, focusing on the development of innovative materials such as two-dimensional materials, optical absorption materials, and superconductors, and the fabrication of photodetectors, solar cells, and novel biosensors. Prof. Qiu's collaboration with Fudan University and the Chinese Academy of Sciences has enhanced his professional endeavors, allowing him to expand his expertise in optoelectronic materials and novel device technologies.

🔬 Contributions and Research Focus

Prof. Qiu’s research is at the forefront of optoelectronic materials and novel device fabrication. His work focuses on developing two-dimensional materials and optical absorption materials that are critical for advanced photodetectors, solar cells, and biosensors. Additionally, his use of first-principles calculations and device quantum transport simulation has led to a deeper understanding of the properties and performance of these devices. Prof. Qiu’s research group, the 2D-X group, has been instrumental in exploring the potential of these materials and devices, bringing new innovations to the field.

🌍 Impact and Influence

Prof. Feng Qiu’s work has had a significant impact on the optoelectronic materials community, both in academia and industry. He is a respected member of the American Chemical Society and the Chinese Physical Society and has made substantial contributions as an editorial board member for several high-impact academic journals, including eScience, Chip, Information & Functional Materials, and the Journal of Infrared and Millimeter Waves. His influence extends through his leadership at Yunnan University, where he serves as a Mid-Youth Backbone Teacher and an outstanding educator under the "Hongyun Gardener" program. Prof. Qiu’s innovative research on optoelectronic materials has also fostered numerous collaborations, furthering advancements in photodetectors, solar cells, and biosensors.

🏆Academic Cites

Prof. Qiu’s work on optoelectronic materials and novel device fabrication has garnered substantial academic recognition. His research is frequently cited by other experts in the field, underscoring the significance of his contributions. His studies on the structure and performance of two-dimensional materials and their applications in photodetectors, solar cells, and biosensors are highly regarded, making him a leading figure in optoelectronic materials research.

🌟 Legacy and Future Contributions

Looking forward, Prof. Feng Qiu is poised to continue leading the field of optoelectronic materials and device fabrication. His future contributions are expected to push the boundaries of two-dimensional material technologies, enhancing the performance and applications of photodetectors, solar cells, and biosensors. Prof. Qiu’s research group will continue to explore new avenues for industrialization, helping to translate academic discoveries into real-world solutions. His legacy will be defined by his groundbreaking work in optoelectronic materials, as well as his commitment to education and scientific collaboration.

📝Optoelectronic Materials and Novel Devices

Prof. Feng Qiu's expertise in optoelectronic materials is evident through his pioneering work in the fabrication of novel devices such as photodetectors, solar cells, and biosensors. His use of first-principles calculations and quantum transport simulation has been instrumental in advancing the understanding of optoelectronic materials. As a leader in the 2D-X group, his research continues to shape the future of optoelectronic materials, providing innovative solutions to real-world challenges.

Notable Publication

📝Interface engineering of silicon/carbon thin-film anodes for high-rate lithium-ion batteries

Authors: L. Tong, P. Wang, W. Fang, X. Guo, W. Bao, Y. Yang, S. Shen, F. Qiu

Journal: ACS Applied Materials & Interfaces

Year: 2020

Citations: 63

📝Recent progress in the preparation and application of quantum dots/graphene composite materials

Authors: L. Tong, F. Qiu, T. Zeng, J. Long, J. Yang, R. Wang, J. Zhang, C. Wang, T. Sun, ...

Journal: RSC Advances

Year: 2017

Citations: 59

📝Photodetectors based on two-dimensional MoS2 and its assembled heterostructures

Authors: T. Hu, R. Zhang, J.P. Li, J.Y. Cao, F. Qiu

Journal: Chip

Year: 2022

Citations: 46

📝Improved electrochemical performance of binder-free multi-layered silicon/carbon thin film electrode for lithium-ion batteries

Authors: L. Tong, P. Wang, A. Chen, F. Qiu, W. Fang, J. Yang, C. Wang, Y. Yang

Journal: Carbon

Year: 2019

Citations: 37

📝Enhancing stability and luminescence quantum yield of CsPbBr3 quantum dots by embedded in borosilicate glass

Authors: B. Zhang, K. Zhang, L. Li, C. Xu, R. Wang, C. Wang, J. Yang, Y. Yang, J. Wang, ...

Journal: Journal of Alloys and Compounds

Year: 2021

Citations: 34

📝Surface oxidation properties in a topological insulator Bi2Te3 film

Authors: J.H. Guo, F. Qiu, Y. Zhang, H.Y. Deng, G.J. Hu, X.N. Li, G.L. Yu, N. Dai

Journal: Chinese Physics Letters

Year: 2013

Citations: 31

📝Lattice Defect Engineering Enables Performance-Enhanced MoS2 Photodetection through a Paraelectric BaTiO3 Dielectric

Authors: W. Zhang, F. Qiu, Y. Li, R. Zhang, H. Liu, L. Li, J. Xie, W. Hu

Journal: ACS Nano

Year: 2021

Citations: 30

Qianxu Wang – Neutral Beam Injector – Best Researcher Award

Posted on 06/02/202506/02/2025 by AMO Physics

Dr. Qianxu Wang - Neutral Beam Injector - Best Researcher Award

Institute of Plasma Physics, Hefei Institutes of Physical Science, Chinese Academy of Sciences - China

Author Profile

🎓 Early Academic Pursuits

Dr. Qianxu Wang’s academic journey began at Anhui Jianzhu University, where he obtained his B.Sc. degree in Building Environment and Energy Applications Engineering from September 2014 to July 2018. He demonstrated a keen interest in energy systems, which led him to pursue a Master’s degree in Refrigeration and Cryogenics at Central South University, completing his M.Sc. in July 2021. His educational path culminated in a Ph.D. in Nuclear Energy Science and Engineering from the University of Science and Technology of China, where he is currently continuing his research, beginning in September 2022.

💼 Professional Endeavors

Dr. Wang has accumulated significant professional experience in the field of nuclear fusion, specifically related to Neutral Beam Injection (NBI) technologies. His key role as a member of the NBI group at the Institute of Plasma Physics, Chinese Academy of Sciences (ASIPP), spans over three years. In this capacity, Dr. Wang has contributed extensively to the commissioning of the EAST NBI and CRAFT NNBI beamlines and support systems. His experience encompasses working on the design, analysis, and commissioning of NBI beamline systems, which are crucial for advancing nuclear fusion research.

🔬 Contributions and Research Focus

Dr. Qianxu Wang’s primary research focus lies in the development of Neutral Beam Injectors (NBI), specifically the cryopumps integral to these systems. He has made notable contributions to the design and development of NBI cryopump integrated test benches, including the successful completion of the CRAFT NNBI cryopump. Currently, he is leading the design and key technological advancements for the BEST NBI cryopump, a crucial component for future nuclear fusion reactors. His research aims to enhance the efficiency and functionality of NBI systems, which are central to achieving sustainable fusion energy.

🌍 Impact and Influence

Dr. Wang’s work has made a profound impact in the field of nuclear fusion research, particularly in the development of Neutral Beam Injector systems. His efforts in advancing the design and functionality of NBI cryopumps have been pivotal in improving the performance of beamlines like EAST and CRAFT NNBI. These advancements not only contribute to the efficiency of fusion reactors but also influence ongoing and future nuclear fusion research worldwide. Dr. Wang’s expertise places him at the forefront of the fusion energy community, and his involvement with various research groups, including the EAST NBI Beamline and Support System Group, has enhanced his professional stature.

🏆Academic Cites

As Dr. Wang continues his research, his work on Neutral Beam Injectors and cryopump technology is gaining recognition in academic circles. His research papers and contributions to nuclear fusion, particularly in relation to NBI systems, have been cited in numerous journals and conferences. His developments in the design and commissioning of beamline systems are becoming foundational knowledge for future research in nuclear energy.

🌟 Legacy and Future Contributions

Dr. Wang’s legacy in the field of nuclear fusion and Neutral Beam Injector technology is poised to expand as he continues to make significant strides in advancing fusion research. His ongoing work with cryopumps, especially the BEST NBI cryopump, will play a pivotal role in enhancing the efficiency of next-generation fusion reactors. Dr. Wang is expected to continue influencing the direction of nuclear fusion technology through his innovative research and design work, leaving a lasting impact on both the academic and practical aspects of nuclear energy.

📝Neutral Beam Injector

Dr. Qianxu Wang’s expertise in Neutral Beam Injector technology, particularly in the development and integration of cryopumps, places him at the cutting edge of fusion research. His innovative work on Neutral Beam Injector cryopumps and beamline systems, including the EAST NBI and CRAFT NNBI projects, positions him as a leader in the field. As he progresses with his research and contributions to the Neutral Beam Injector systems, Dr. Wang’s work will continue to shape the future of nuclear fusion energy.

Notable Publication

📝Analysis and optimization of LN2 two-phase flow in CRAFT NNBI cryopump

Journal: Nuclear Engineering and Technology

Year: 2025

Contributors: Qianxu Wang, Yuanlai Xie, Huihui Hong, Yang Zhu, Fang Wang, Kun Tian, Bin Li

📝Simulation and experiment of CRAFT NNBI cryopump

Journal: Fusion Engineering and Design

Year: 2024

Contributors: Qianxu Wang, Yuanlai Xie, Huihui Hong, Yang Zhu, Fang Wang, Yao Jiang, Jianjie Yao

Jinming Zeng – Electrochromism – Best Researcher Award

Posted on 06/02/202506/02/2025 by AMO Physics

Dr. Jinming Zeng - Electrochromism - Best Researcher Award

Jiangxi University of Science and Technology - China

Author Profile

🎓 Early Academic Pursuits

Dr. Jinming Zeng's academic journey began with his foundational studies in Polymer Chemistry and Physics, culminating in a Ph.D. from South China University of Technology, PR China. His early academic pursuits focused on the innovative intersection of materials science and energy-efficient technologies, setting the stage for a distinguished career in the preparation and application of multifunctional materials. His deep commitment to advancing smart materials technology laid the groundwork for his future research in electrochromic materials.

💼 Professional Endeavors

Currently, Dr. Zeng serves as an Associate Professor at the College of Rare Earths, Jiangxi University of Science and Technology, PR China. He is deeply involved in academic research and development within the realm of smart and energy-efficient materials, particularly electrochromic devices. Dr. Zeng has overseen several national, provincial, and ministerial-level projects, furthering the application of electrochromic materials in energy-saving technologies such as electrochromic smart windows, electrochromic displays, and visualized energy storage. His professional endeavors include extensive collaboration with various scientific organizations, including his recent election to the Electrochromic Professional Committee of the Chinese Optical Society in 2024.

🔬 Contributions and Research Focus

Dr. Zeng's primary research focus lies in the preparation and application of new multifunctional electrochromic energy-saving materials. His work has significantly advanced the field of electrochromism, particularly in applications such as electrochromic smart windows, electrochromic displays, and visualized energy storage. Dr. Zeng has made substantial contributions to the development of electrochromic materials that offer energy efficiency, environmental sustainability, and enhanced functionality. His research has explored both the scientific underpinnings and practical applications of electrochromism, driving innovation in smart materials and energy-efficient technologies.

🌍 Impact and Influence

Dr. Zeng’s research has had a profound impact on the development of electrochromic technologies. His contributions to the field of electrochromism have influenced both academic research and industrial applications, leading to the advancement of energy-saving materials that are poised to revolutionize sectors such as building technologies, displays, and energy storage systems. Dr. Zeng’s influence extends beyond his own research, as he continues to mentor future generations of scientists and collaborate with professionals across disciplines to address global energy challenges.

🏆Academic Cites

Dr. Zeng’s work has been widely recognized and cited in leading academic journals, reflecting his substantial contributions to the field of electrochromism. His 33 SCI papers, published in prestigious journals such as Chemical Engineering Journal, ACS Applied Materials & Interfaces, Journal of Colloid and Interfaces, Polymer Degradation and Stability, Applied Surface Science, Electrochimica Acta, and Physics Chemistry Chemical Physics, highlight the broad scope and impact of his research. His academic citations continue to grow as his work gains recognition in the scientific community.

🌟 Legacy and Future Contributions

Dr. Jinming Zeng’s legacy is built on his groundbreaking research in electrochromism and its applications in energy-efficient technologies. Moving forward, his future contributions are expected to further enhance the functionality of electrochromic materials and expand their commercial viability. As he continues to lead research projects at the national and provincial levels, Dr. Zeng is poised to make lasting contributions to the development of smart, energy-saving technologies, cementing his legacy as a leading figure in the field of electrochromism.

📝Electrochromism

Dr. Zeng’s expertise in electrochromism has been pivotal in advancing the development of smart materials for energy-efficient technologies. His work in electrochromism has led to innovative applications, including electrochromic smart windows and electrochromic displays, which are at the forefront of energy-saving technologies. Through his continued research and contributions to electrochromism, Dr. Zeng is shaping the future of energy-efficient and sustainable materials in various industrial sectors.

Notable Publication

📝Synthesis of BiOBr/graphene oxide photocatalyst assisted by sodium dodecyl sulfate for efficient degradation of organic pollutants

Authors: Yang, J., Liu, Y., Wu, J., Liang, T., Zeng, J.

Journal: Applied Organometallic Chemistry

Year: 2024

Citations: 0

📝Construction of Bi2S3/FeWO4 Z-Scheme heterojunction for efficient photo-Fenton degradation of antibiotics: Performance and degradation mechanism

Authors: Zhu, W., Wang, Y., Chen, J., Zeng, J., Liang, T.

Journal: Journal of Environmental Chemical Engineering

Year: 2024

Citations: 0

📝Triarylamine-based polyimide COFs for achieving high performance ambipolar multi-color electrochromic energy-storage films

Authors: Huang, L., Guo, R., Qiu, Q., Qi, X., Liu, P.

Journal: Chemical Engineering Journal

Year: 2024

Citations: 0

Weipeng Hu – Nonlinear Dynamics – Best Researcher Award

Posted on 06/02/202506/02/2025 by AMO Physics

Prof. Weipeng Hu - Nonlinear Dynamics - Best Researcher Award

Xi’an University of Technology - China

Author Profile

🎓 Early Academic Pursuits

Professor Weipeng Hu’s academic journey began with his study of Civil Engineering at Northwestern Polytechnical University, where he earned his Bachelor’s degree in 2003. He furthered his education by obtaining a Master of Engineering in Constructional Engineering in 2006 and a Doctor of Engineering in Engineering Mechanics in 2008 from the same institution. His early academic pursuits laid a strong foundation in engineering principles, particularly in the areas of nonlinear dynamics and structural analysis.

💼 Professional Endeavors

Professor Hu’s professional career spans prestigious institutions across China and abroad. He has held several prominent positions, including Associate Professor and Professor at Northwestern Polytechnical University, and currently serves as a Professor at Xi’an University of Technology. His international experience includes postdoctoral research at Northwestern Polytechnical University, as well as research fellowships at the University of Liverpool, UK, and the University of British Columbia, Canada. These professional endeavors have significantly shaped his research contributions, especially in nonlinear dynamics and structural dynamics.

🔬 Contributions and Research Focus

Professor Hu is a recognized leader in the field of Nonlinear Dynamics, with particular focus on the numerical methods of nonlinear dynamic systems. His expertise lies in developing structure-preserving methods for infinite-dimensional non-conservative dynamic systems, an extension of the work originally proposed by Prof. Feng. This approach has led to significant innovations, including the development of symplectic dimensionality reduction methods, multi-symplectic order reduction methods, and generalized multi-symplectic methods for dissipative dynamic systems. These breakthroughs are aimed at improving the efficiency and stability of numerical analyses, particularly for high-order nonlinear Hamiltonian systems and dissipative dynamic systems.

Professor Hu’s research also includes the study of energy transfer and dissipation mechanisms in ultra-large, ultra-flexible structures, with a particular emphasis on the Solar Power Satellite System. His contributions have advanced the structure-preserving theory, expanding it from finite-dimensional conservative systems to infinite-dimensional non-conservative systems.

🌍 Impact and Influence

Professor Hu’s impact extends far beyond the classroom and laboratory. His innovative work in Nonlinear Dynamics has influenced a wide range of applications in engineering, including energy systems and space technology. His research has received significant recognition, including several awards for his contributions to science and technology. He was honored with the first prize of the 2023 Science and Technology Award of Shaanxi Universities, as well as the first prize in 2017 and 2018, underscoring his leadership in the field. His work has also received funding from major national research bodies, including the National Natural Science Foundation of China, ensuring continued progress in his areas of expertise.

🏆Academic Cites

Professor Hu has published over 60 papers in SCI-indexed journals, with several of his works earning ESI Highly Cited Paper status. His research has been widely cited, reflecting the profound impact of his contributions to Nonlinear Dynamics and structural engineering. His academic citations continue to serve as a reference for scholars and researchers exploring related topics in nonlinear dynamics, particularly in the context of high-dimensional and complex systems.

🌟 Legacy and Future Contributions

Professor Hu’s legacy in Nonlinear Dynamics is already established through his numerous publications, awards, and innovations. Looking forward, he plans to continue refining the structure-preserving theory for even more complex systems and to explore new applications in aerospace and energy systems. His future contributions are poised to further solidify his influence in the engineering and dynamics community, shaping the development of new technologies and methodologies in the years to come.

Nonlinear Dynamics

Professor Weipeng Hu’s extensive contributions to Nonlinear Dynamics have not only advanced the theoretical foundations of the field but also contributed practical solutions to complex engineering problems. His research continues to evolve, pushing the boundaries of what is possible in the study of Nonlinear Dynamics and its application to large-scale engineering systems. The work of Professor Hu remains integral to the development of cutting-edge solutions in the field, ensuring that his contributions will have a lasting impact on future generations of engineers and researchers.

📝Notable Publication

📝Generalized multi-symplectic integrators for a class of Hamiltonian nonlinear wave PDEs

Authors: W. Hu, Z. Deng, S. Han, W. Zhang

Journal: Journal of Computational Physics

Year: 2013

Citations: 145

📝Symmetry breaking of infinite-dimensional dynamic system

Authors: W. Hu, Z. Wang, Y. Zhao, Z. Deng

Journal: Applied Mathematics Letters

Year: 2020

Citations: 128

📝Vibration and elastic wave propagation in spatial flexible damping panel attached to four special springs

Authors: W. Hu, C. Zhang, Z. Deng

Journal: Communications in Nonlinear Science and Numerical Simulation

Year: 2020

Citations: 115

📝Internal resonance of a flexible beam in a spatial tethered system

Authors: W. Hu, J. Ye, Z. Deng

Journal: Journal of Sound and Vibration

Year: 2020

Citations: 108

📝Coupling dynamic behaviors of flexible stretching hub-beam system

Authors: W. Hu, M. Xu, J. Song, Q. Gao, Z. Deng

Journal: Mechanical Systems and Signal Processing

Year: 2021

Citations: 91

📝Mechanoelectrical flexible hub-beam model of ionic-type solvent-free nanofluids

Authors: W. Hu, Y. Huai, M. Xu, X. Feng, R. Jiang, Y. Zheng, Z. Deng

Journal: Mechanical Systems and Signal Processing

Year: 2021

Citations: 82

📝Chaos in an embedded single-walled carbon nanotube

Authors: W. Hu, Z. Deng, B. Wang, H. Ouyang

Journal: Nonlinear Dynamics

Year: 2013

Citations: 66

📝Minimum control energy of spatial beam with assumed attitude adjustment target

Authors: W. Hu, L. Yu, Z. Deng

Journal: Acta Mechanica Solida Sinica

Year: 2020

Citations: 59

📝Almost structure-preserving analysis for weakly linear damping nonlinear Schrödinger equation with periodic perturbation

Authors: W. Hu, Z. Deng, T. Yin

Journal: Communications in Nonlinear Science and Numerical Simulation

Year: 2017

Citations: 55

Andy Anderson Bery – Machine Learning in Geophysics – Best Researcher Award

Posted on 05/02/202507/02/2025 by AMO Physics

Assoc. Prof. Dr. Andy Anderson Bery - Machine Learning in Geophysics - Best Researcher Award

Universiti Sains Malaysia - Malaysia

Author Profile