Guoxing Li | Energy | Best Researcher Award

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Dr. Guoxing Li | Energy | Best Researcher Award

Chang’an University, China

Guoxing Li is an emerging researcher specializing in sustainable energy systems, with particular expertise in hydrogen production, combustion chemistry, and supercritical water processes. After obtaining his PhD from Xi’an Jiaotong University in July 2022, he began his academic career as a lecturer at the School of Energy and Electrical Engineering, Chang’an University. His research has made significant contributions to the understanding of reaction kinetics and combustion behavior in complex energy systems, focusing on both theoretical and experimental approaches. Guoxing Li has published extensively in high-impact international journals and has collaborated with leading scholars in the field. His work stands out for its combination of computational modeling, kinetic analysis, and innovative designs for energy conversion processes, which offer solutions for cleaner and more efficient energy production. His research is highly relevant in the global transition towards sustainable and low-carbon energy systems. Guoxing Li’s scientific rigor, growing leadership, and impactful research output position him as a rising talent in the energy research community. His continuous efforts are paving the way for advancements in hydrogen utilization and supercritical water technologies, which hold great promise for addressing current energy and environmental challenges.

Professional Profile

Education

Guoxing Li earned his PhD degree from Xi’an Jiaotong University, one of China’s premier engineering institutions, in July 2022. His doctoral studies focused on advanced combustion chemistry, reaction kinetics, and the utilization of supercritical water in energy applications. Throughout his academic journey, he developed a strong foundation in chemical engineering, thermodynamics, and computational modeling, which became the backbone of his research expertise. During his time at Xi’an Jiaotong University, Guoxing Li worked closely with renowned faculty and engaged in collaborative projects that shaped his deep understanding of energy systems. His education emphasized both theoretical learning and practical laboratory research, allowing him to master a range of scientific tools and techniques related to sustainable energy. His rigorous training has equipped him to design, analyze, and optimize complex chemical reactions for cleaner energy production. The multidisciplinary nature of his doctoral work has enabled him to address real-world energy challenges from both a chemical and engineering perspective. Guoxing Li’s academic background continues to influence his current research and teaching, fostering a blend of scientific inquiry and practical application that benefits both his students and the broader research community.

Professional Experience

Guoxing Li began his professional career as a lecturer at the School of Energy and Electrical Engineering, Chang’an University, shortly after completing his doctoral studies in 2022. In this role, he has been actively involved in both teaching and research, contributing to the academic growth of students while advancing his own investigations into sustainable energy systems. His teaching responsibilities include subjects related to energy conversion, combustion chemistry, and environmental protection technologies, where he integrates his research findings into the classroom. Professionally, Guoxing Li has made significant contributions to the development of supercritical water oxidation processes, kinetic modeling of hydrogen combustion, and innovative solutions for chemical reaction systems. His career is marked by strong collaborations with international experts and consistent publication in top-tier journals, which demonstrate his ability to produce high-quality, impactful research. His professional journey is characterized by steady growth, scientific integrity, and a focus on addressing energy-related environmental challenges. As a young academic, he is building a reputation for bridging the gap between theoretical modeling and practical energy solutions, contributing not only to academia but also to the potential advancement of industrial applications in the field of sustainable energy.

Research Interests

Guoxing Li’s research interests are centered on sustainable energy systems, with a particular focus on hydrogen production, combustion chemistry, and the application of supercritical water technologies. He is passionate about advancing the understanding of oxidation kinetics in hydrogen and hydrocarbon-based fuels under supercritical conditions, which is essential for developing efficient and clean energy conversion processes. His work often integrates computational methods, such as ReaxFF molecular dynamics simulations and detailed kinetic modeling, to explore reaction mechanisms at a fundamental level. Guoxing Li also investigates hydrothermal flames, water gas shift reactions, and the oxidative degradation of pollutants in supercritical water, contributing to both energy generation and environmental protection. His interdisciplinary approach allows him to address complex energy challenges from both chemical and engineering perspectives. By focusing on clean combustion and innovative reactor designs, his research aims to reduce greenhouse gas emissions and promote sustainable hydrogen utilization. He is particularly interested in the future applications of supercritical water reactors for waste treatment and energy recovery, as well as the role of hydrogen as a key player in decarbonizing the energy sector. Guoxing Li’s forward-thinking research is aligned with global energy transition goals and climate action priorities.

Research Skills

Guoxing Li possesses a comprehensive set of research skills that enable him to tackle complex energy and combustion-related challenges effectively. His expertise in kinetic modeling is one of his core strengths, particularly in developing detailed reaction mechanisms for hydrogen oxidation and hydrocarbon combustion under supercritical water conditions. He is proficient in advanced computational simulation tools, including ReaxFF molecular dynamics and Density Functional Theory (DFT) methods, which he uses to predict and analyze chemical reaction behaviors at both macroscopic and molecular levels. Additionally, Guoxing Li has extensive hands-on experience in experimental design, reactor operation, and supercritical water processing, allowing him to validate his computational models with laboratory results. He is skilled in data analysis, thermodynamic calculations, and chemical kinetics, and adept at using specialized software for energy system modeling. His ability to integrate simulation with practical experimentation distinguishes his work and enhances its scientific credibility. Guoxing Li also demonstrates strong capabilities in scientific writing, project management, and interdisciplinary collaboration, which contribute to his growing impact in the research community. These skills collectively support his goal of developing innovative, efficient, and environmentally friendly energy solutions.

Awards and Honors

Although specific awards and honors for Guoxing Li have not been explicitly listed, his publication record and collaborative work with internationally recognized researchers reflect a high level of academic recognition. His consistent contributions to top-tier journals such as Energy & Fuels, Fuel, Process Safety and Environmental Protection, Journal of Cleaner Production, and Renewable and Sustainable Energy Reviews demonstrate his research excellence and growing influence in the field of sustainable energy. His involvement in cutting-edge research topics such as hydrogen combustion, supercritical water technologies, and clean energy conversion processes positions him as a rising talent with strong prospects for future academic and professional accolades. His articles often address innovative solutions to energy and environmental problems, which likely contribute to positive peer recognition and opportunities for further research collaborations. As Guoxing Li’s career progresses, his current trajectory suggests he will be a strong candidate for future research awards, fellowships, and leadership roles in energy-focused academic societies. His potential for receiving awards lies in his ability to translate complex chemical processes into practical, impactful energy solutions, advancing both scientific knowledge and environmental sustainability.

Conclusion

Guoxing Li is an accomplished early-career researcher whose contributions to the field of sustainable energy are both timely and impactful. His work on hydrogen combustion, kinetic modeling, and supercritical water oxidation addresses some of the most critical challenges in clean energy development and environmental protection. Guoxing Li’s ability to combine computational simulations with experimental validation showcases his scientific rigor and versatility. His educational background, professional growth, and consistently strong research output indicate a deep commitment to advancing knowledge in sustainable energy systems. Although there is room to expand his interdisciplinary collaborations and industrial applications, his current trajectory positions him as a future leader in the field. His research is not only academically significant but also holds the potential for real-world impact in the global transition to low-carbon and hydrogen-based energy solutions. Guoxing Li’s achievements thus far make him a highly suitable candidate for further recognition, including prestigious research awards. His continued dedication to innovation, scientific integrity, and energy sustainability will undoubtedly contribute to his long-term success and influence in both the academic and industrial energy sectors.

Publications Top Notes

1. Recent Progress and Prospects of Hydrogen Combustion Chemistry in the Gas Phase

  • Type: Review

2. Recent Progress and Prospects of Hydrothermal Flames for Efficient and Clean Energy Conversion

  • Type: Review

Li Yan | Energy | Best Researcher Award

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Dr. Li Yan | Energy | Best Researcher Award

Assistant Researcher from Beijing University of Technology, China

Dr. Yan Li is an accomplished researcher in the field of energy materials, currently serving as an Assistant Researcher at Beijing University of Technology. With a strong academic background and postdoctoral training at one of China’s most prestigious universities, he has developed expertise in designing and synthesizing advanced cathode materials for both lithium-ion and sodium-ion batteries. His work focuses on improving battery performance, safety, and understanding degradation mechanisms through cutting-edge in situ and operando transmission electron microscopy (TEM) techniques. Dr. Li’s contribution lies not only in material synthesis but also in developing novel characterization methods to address the fundamental scientific challenges related to energy storage systems. His multidisciplinary approach combines materials science, electrochemistry, and electron microscopy to explore next-generation battery technologies. Dr. Li is emerging as a strong presence in the research community, known for his technical depth, innovative thinking, and commitment to solving real-world energy problems. His current research aims to enhance the reliability and lifespan of battery systems, which are crucial for applications in electric vehicles, portable electronics, and grid storage. Dr. Yan Li continues to make substantial contributions to the scientific community and has the potential to influence global advancements in sustainable energy technologies.

Professional Profile

Education

Dr. Yan Li obtained his Doctor of Philosophy (Ph.D.) degree in 2016 from Nanjing Tech University, Nanjing, China, where he specialized in the field of materials science and engineering with a particular emphasis on electrochemical energy storage systems. His academic journey began with a solid foundation in chemistry and material science, which later evolved into specialized research in battery technologies. During his Ph.D. studies, Dr. Li gained rigorous training in materials synthesis, electrochemical analysis, and structural characterization, setting the groundwork for his future innovations in energy storage. His doctoral thesis likely explored aspects of material behavior under electrochemical conditions, especially within battery systems. His academic excellence and research potential were evident early on, leading to postdoctoral opportunities at leading institutions. Dr. Li’s commitment to academic rigor and continuous learning has enabled him to stay at the forefront of energy research. The comprehensive nature of his education has played a critical role in shaping his ability to address complex challenges in the development of high-performance and safe battery materials, making him a valuable asset in both academic and industrial research environments.

Professional Experience

Dr. Yan Li is currently employed as an Assistant Researcher at Beijing University of Technology, where he is actively involved in energy materials research. Before his current role, he worked as a Postdoctoral Researcher in the Automotive Department at Tsinghua University, one of China’s top-tier institutions. During his postdoctoral tenure, he contributed to projects that explored the performance and safety of batteries in vehicular applications, particularly electric vehicles. His responsibilities included not only experimental research but also data analysis, project planning, and collaboration with cross-disciplinary teams. These roles provided him with invaluable experience in applying academic research to real-world industrial needs. At Beijing University of Technology, Dr. Li continues to expand his research on lithium-ion and sodium-ion battery technologies. His professional work integrates both fundamental research and applied science, offering insights into battery degradation, safety, and longevity. This professional journey underscores his ability to contribute to high-impact research projects while also nurturing the skills required for academic leadership and innovation. Through these experiences, Dr. Li has built a strong foundation for further academic achievements and collaborative ventures in the global energy research community.

Research Interest

Dr. Yan Li’s research interests lie at the intersection of materials science, electrochemistry, and energy storage systems. He is particularly focused on the design, synthesis, and optimization of cathode materials for lithium-ion and sodium-ion batteries. These energy storage technologies are pivotal for the future of electric vehicles, renewable energy integration, and portable electronic devices. His research explores new material chemistries that offer higher energy density, better thermal stability, and longer cycle life. One of the most distinctive aspects of Dr. Li’s work is his application of in situ and operando transmission electron microscopy (TEM) to study the real-time structural and chemical changes occurring in battery materials during operation. This technique allows for the direct observation of degradation mechanisms, providing critical insights that can lead to safer and more durable battery systems. Additionally, Dr. Li is interested in exploring environmentally friendly and cost-effective alternatives to conventional battery materials. His multidisciplinary approach and continuous pursuit of innovation highlight his dedication to solving pressing energy challenges and advancing battery technology for broader societal impact.

Research Skills

Dr. Yan Li possesses a diverse and robust set of research skills that make him a leading expert in the field of energy storage materials. His core competencies include advanced materials synthesis, especially in the development of cathode materials for lithium-ion and sodium-ion batteries. He is proficient in a wide array of characterization techniques, with specialized expertise in in situ and operando transmission electron microscopy (TEM), which allows him to analyze material transformations and degradation processes in real-time during battery operation. His skills also encompass electrochemical testing, such as cyclic voltammetry, galvanostatic charge/discharge measurements, and impedance spectroscopy, which are essential for evaluating the performance of battery materials. Dr. Li has hands-on experience with battery fabrication techniques, including electrode preparation, coin-cell assembly, and safety testing protocols. Additionally, he is skilled in data analysis, scientific writing, and project management, making him capable of leading and executing comprehensive research projects. His ability to integrate theoretical knowledge with experimental practice enables him to develop innovative solutions in the realm of energy storage, ensuring both academic excellence and industrial relevance.

Awards and Honors

While specific awards and honors received by Dr. Yan Li have not been publicly listed, his academic and professional trajectory suggests a strong record of recognition and merit. Being selected for a postdoctoral position at Tsinghua University, a globally recognized institution, is itself an indicator of high academic standing and research potential. His current appointment as an Assistant Researcher at Beijing University of Technology also reflects his capabilities and the trust placed in him by academic peers and senior faculty. It is likely that he has received institutional and project-based acknowledgments for his work on battery materials and electrochemical analysis. Furthermore, Dr. Li’s contributions to cutting-edge topics such as in situ characterization and energy storage mechanisms may have positioned him to receive future recognitions in the form of research grants, invitations to conferences, and publication awards. As his research output grows and gains visibility, he is well-positioned to earn national and international honors that further validate his contributions to the field of materials science and energy technology.

Conclusion

Dr. Yan Li is a promising and capable researcher with a strong academic foundation, diverse professional experience, and clear research focus in the field of advanced energy storage systems. His work on lithium-ion and sodium-ion battery cathode materials, combined with his innovative application of in situ and operando TEM, places him at the forefront of modern materials research. Dr. Li exhibits a balanced skill set that includes experimental technique, critical analysis, and interdisciplinary collaboration. While he is still in the early stages of his independent research career, his track record shows a consistent trajectory of growth and excellence. To further strengthen his global research profile, increased publication in high-impact journals, active international collaboration, and participation in global energy forums will be advantageous. Overall, Dr. Yan Li is highly suitable for recognition through a Best Researcher Award. His work not only contributes to academic knowledge but also addresses critical challenges in sustainable energy storage, making his research impactful both scientifically and societally. He represents the next generation of materials scientists capable of driving innovation in the energy sector.

Publication Top Notes

1. Removal of residual contaminants by minute-level washing facilitates the direct regeneration of spent cathodes from retired EV Li-ion batteries

  • Authors: Guo, Yi; Li, Yang; Qiu, Kai; Li, Yan; Yuan, Weijing; Li, Chenxi; Rui, Xinyu; Shi, Lewei; Hou, Yukun; Liu, Saiyue et al.

  • Year: 2025

2. Cryo-Sampling Enables Precise Evaluation of Thermal Stability of a Ni-Rich Layered Cathode

  • Authors: Mindi Zhang; Yan Li; Manling Sui; Pengfei Yan

  • Year: 2025

3. Cross-scale deciphering thermal failure process of Ni-rich layered cathode

  • Authors: Ding, Yang; Li, Yan; Xu, Ruoyu; Han, Xiao; Huang, Kai; Ke, Xiaoxing; Wang, Bo; Sui, Manling; Yan, Pengfei

  • Year: 2024

4. Early-stage latent thermal failure of single-crystal Ni-rich layered cathode

  • Authors: Han, Xiao; Xu, Ruoyu; Li, Yan; Ding, Yang; Zhang, Manchen; Wang, Bo; Ke, Xiaoxing; Sui, Manling; Yan, Pengfei

  • Year: 2024

5. Selective core-shell doping enabling high performance 4.6 V-LiCoO₂

  • Authors: Xia, Yueming; Feng, Jianrui; Li, Jinhui; Li, Yan; Zhang, Zhengfeng; Wang, Xiaoqi; Shao, Jianli; Sui, Manling; Yan, Pengfei

  • Year: 2024

6. Toward a high-voltage practical lithium ion batteries with ultraconformal interphases and enhanced battery safety

  • Authors: Li, Yan; Li, Jinhui; Ding, Yang; Feng, Xuning; Liu, Xiang; Yan, Pengfei; Sui, Manling; Ouyang, Minggao

  • Year: 2024

7. Advanced characterization guiding rational design of regeneration protocol for spent-LiCoO₂

  • Authors: Mu, Xulin; Huang, Kai; Zhu, Genxiang; Li, Yan; Liu, Conghui; Hui, Xiaojuan; Sui, Manling; Yan, Pengfei

  • Year: 2023

8. Mitigating Twin Boundary-Induced Cracking for Enhanced Cycling Stability of Layered Cathodes

  • Authors: Mu, Xulin; Hui, Xiaojuan; Wang, Mingming; Wang, Kuan; Li, Yan; Zhang, Yuefei; Sui, Manling; Yan, Pengfei

  • Year: 2023

9. Development of cathode-electrolyte-interphase for safer lithium batteries

  • Authors: Wu, Yu; Liu, Xiang; Wang, Li; Feng, Xuning; Ren, Dongsheng; Li, Yan; Rui, Xinyu; Wang, Yan; Han, Xuebing; Xu, Gui-Liang et al.

  • Year: 2021

10. Unlocking the self-supported thermal runaway of high-energy lithium-ion batteries

  • Authors: Hou, Junxian; Feng, Xuning; Wang, Li; Liu, Xiang; Ohma, Atsushi; Lu, Languang; Ren, Dongsheng; Huang, Wensheng; Li, Yan; Yi, Mengchao et al.

  • Year: 2021

 

 

 

Yige Zhao | Energy | Best Researcher Award

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Assoc. Prof. Dr. Yige Zhao | Energy | Best Researcher Award

Dr. Yige Zhao is an accomplished Associate Professor at the School of Materials Science and Engineering, Zhengzhou University, with a research focus on advanced energy materials and devices. Her work spans the development of innovative solutions in hydrogen energy, electrocatalysis, and next-generation energy storage systems such as metal-air and lithium-sulfur batteries. With a strong educational foundation from Beijing University of Chemical Technology and rich professional experience in academia, Dr. Zhao has established herself as a leading expert in clean energy research. She has been at the forefront of several major research initiatives, including national and provincial-level projects, and maintains active collaborations with industry partners to ensure practical application of her work. In addition to her robust research profile, Dr. Zhao is a dedicated educator, delivering core undergraduate and innovation-based courses and mentoring graduate students. She has contributed significantly to academic literature with publications in high-impact journals and holds patents on novel electrocatalysts. Recognized for her excellence in both research and teaching, Dr. Zhao has received multiple honors and awards at the university and provincial levels. Her contributions are shaping the future of sustainable energy technologies in China and beyond, demonstrating her commitment to scientific innovation, education, and real-world impact.

Professional Profile

Education

Dr. Yige Zhao’s academic journey began at Beijing University of Chemical Technology, where she earned both her bachelor’s and doctoral degrees in Materials Science and Engineering. From 2009 to 2013, she pursued her undergraduate studies, laying a strong foundation in material chemistry, polymer science, and electrochemical systems. Following her bachelor’s degree, she continued her education at the same institution, completing her Ph.D. in 2018. During her doctoral research, she delved deeply into the synthesis and characterization of energy-related materials, with a specific focus on their application in sustainable technologies such as fuel cells and water-splitting devices. Her rigorous academic training equipped her with comprehensive knowledge in materials processing, advanced characterization techniques, and catalytic mechanisms. The Ph.D. experience also fostered her ability to independently manage research projects and collaborate across disciplines. Her formal education, combined with hands-on lab experience and participation in national-level projects during her doctoral studies, has been crucial in shaping her future career in academia and research. The excellence of her academic record not only underscores her technical competence but also reflects her persistent dedication to addressing global energy challenges through scientific innovation.

Professional Experience

Since July 2018, Dr. Yige Zhao has been affiliated with Zhengzhou University’s School of Materials Science and Engineering, initially joining as a lecturer and subsequently promoted to the role of Associate Professor. Her professional experience in this capacity has been defined by her leadership in academic instruction, research innovation, and student mentorship. She has played a pivotal role in developing and teaching core undergraduate courses such as Electrochemistry, New Energy Device Innovation Practice, and Innovation and Entrepreneurship Training. These courses are aligned with her research specializations and have been instrumental in preparing students for careers in clean energy technologies. In addition to her teaching duties, Dr. Zhao has successfully led several funded research projects sponsored by the National Natural Science Foundation of China, Henan Provincial Science and Technology Department, and other institutional platforms. Her involvement with industrial projects through horizontal enterprise collaborations further reflects her practical orientation and commitment to technology transfer. She also supervises graduate research through the National Joint Research Center for Low-Carbon Environmental Protection Materials. With an emphasis on collaborative innovation, Dr. Zhao’s professional journey demonstrates a balanced blend of theoretical knowledge and application-driven research, marking her as a dynamic contributor to China’s sustainable energy ambitions.

Research Interest

Dr. Zhao’s research interests are centered around the synthesis, modification, and application of advanced materials for clean energy conversion and storage. Her work addresses critical challenges in hydrogen energy production, storage, and utilization, as well as the development of efficient electrocatalysts for oxygen evolution and reduction reactions. She has a particular interest in the design of bifunctional materials that enable high-performance metal-air batteries and overall water splitting devices. Dr. Zhao’s investigations extend to lithium-sulfur and zinc-air battery systems, aiming to enhance their stability, conductivity, and charge-discharge efficiency through nanostructuring and surface engineering. She is especially adept at designing carbon-based nanomaterials doped with transition metals and heteroatoms to boost electrocatalytic activity. Her work also involves in situ characterization techniques to explore the underlying mechanisms of energy storage reactions. These multidisciplinary efforts integrate chemistry, materials science, and environmental engineering to create novel solutions for next-generation energy needs. Dr. Zhao’s long-term goal is to contribute to the global transition to low-carbon technologies by developing scalable and cost-effective materials that support sustainable energy systems. Her research is both fundamental and applied, providing innovative directions in material design for clean energy technologies.

Research Skills

Dr. Yige Zhao possesses an advanced skill set in both experimental and analytical aspects of materials research, particularly in the field of electrocatalysis and energy storage devices. Her expertise includes the synthesis of nanostructured materials such as doped carbon nanofibers, porous carbon matrices, and hybrid composites with metal-based active sites. She is highly proficient in techniques like electrospinning, chemical vapor deposition, and hydrothermal synthesis. Dr. Zhao also brings deep experience in utilizing high-end characterization tools such as X-ray photoelectron spectroscopy (XPS), transmission electron microscopy (TEM), scanning electron microscopy (SEM), and in situ electrochemical methods to probe catalytic mechanisms. She is skilled in electrochemical testing techniques, including cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), and linear sweep voltammetry (LSV), crucial for evaluating electrocatalyst performance. Additionally, she has a demonstrated ability to design experimental systems for full-cell battery evaluation, including zinc-air and lithium-sulfur batteries. Dr. Zhao’s interdisciplinary skills enable her to bridge material design with device integration, allowing a holistic approach to innovation in energy technologies. Her ability to conduct mechanistic studies, coupled with process optimization and scale-up, reflects a rare blend of theoretical insight and practical implementation capacity.

Awards and Honors

Dr. Yige Zhao has received numerous accolades recognizing her contributions to scientific research and education. Among the most prestigious is the Henan Provincial Department of Education Science and Technology Achievement Award, which highlights the significance of her innovations in energy materials. She was also awarded the First Prize for Excellent Scientific Papers by the same department, reflecting the high academic quality and impact of her publications. Her role as a Mentor for the National Innovation and Entrepreneurship Training Program for University Students underlines her commitment to fostering research talent and promoting creativity among the next generation. At Zhengzhou University, Dr. Zhao has been consistently recognized for her excellence in student mentorship and academic leadership, earning titles such as Outstanding Undergraduate Thesis Advisor and Excellent Class Advisor. These honors are a testament to her holistic contributions—not just in laboratory research but also in education, leadership, and student engagement. The range of awards from both institutional and governmental levels affirms her status as a prominent figure in the field of energy materials and highlights her ongoing influence in advancing both academic scholarship and sustainable technologies.

Conclusion

In conclusion, Dr. Yige Zhao stands out as a highly accomplished researcher and academic leader in the field of new energy materials and devices. Her comprehensive educational background, innovative research contributions, and dedication to teaching make her an exemplary candidate for recognition in any competitive award platform. She has made significant strides in addressing pressing energy challenges through her work on hydrogen energy, metal-air batteries, and electrocatalysis, combining fundamental science with practical applications. Her published work in top-tier journals and patent contributions underscore her scientific excellence, while her success in securing national and provincial research funding demonstrates her leadership and credibility in the research community. Additionally, her active involvement in student development and academic instruction reflects a deep commitment to knowledge transfer and mentorship. As global energy systems shift toward sustainability, the work of scientists like Dr. Zhao becomes increasingly vital. Her interdisciplinary approach, strategic vision, and hands-on research skills position her as a driving force in clean energy innovation. Dr. Zhao not only meets but exceeds the criteria for the Best Researcher Award, making her a deserving candidate whose contributions are already making a meaningful impact in the field of sustainable energy science.

Publications Top Notes

A Parallel Array Structured Cobalt Sulfide/Nitrogen Doped Carbon Nanocage/Carbon Fiber Composite Based on Microfluidic Spinning Technology

  • Authors: Yige Zhao, Ting Li, Qing Wang, Yinyin Ai, Ruohan Hou, Aneela Habib, Guosheng Shao, Feng Wang, Peng Zhang

  • Year: 2024

2. Bead-Structured Triple-Doped Carbon Nanocage/Carbon Nanofiber Composite as a Bifunctional Oxygen Electrocatalyst for Zn–Air Batteries

  • Authors: Qing Wang, Yige Zhao, Bo Zhang, Yukun Li, Xiang Li, Guosheng Shao, Peng Zhang

  • Year: 2024

3. One-Pot Synthesis of Nitrogen-Doped Porous Carbon Derived from the Siraitia grosvenorii Peel for Rechargeable Zinc–Air Batteries

  • Authors: Lu Li, Mengyao Zhao, Bo Zhang, Guosheng Shao, Yige Zhao

  • Year: 2023

4. Li Intercalation in an MoSe₂ Electrocatalyst: In Situ Observation and Modulation of Its Precisely Controllable Phase Engineering for a High‐Performance Flexible Li‐S Battery

  • Authors: Yunke Wang, Yige Zhao, Kangli Liu, Shaobin Wang, Neng Li, Guosheng Shao, Feng Wang, Peng Zhang

  • Year: 2023

5. Watermelon Peel‐Derived Nitrogen‐Doped Porous Carbon as a Superior Oxygen Reduction Electrocatalyst for Zinc‐Air Batteries

  • Authors: Lu Li, Zhiheng Wu, Jin Zhang, Yige Zhao, Guosheng Shao

  • Year: 2021

6. Sponge Tofu-like Graphene-Carbon Hybrid Supporting Pt–Co Nanocrystals for Efficient Oxygen Reduction Reaction and Zn–Air Battery

  • Authors: Yige Zhao, Lu Li, Dengke Liu, Zhiheng Wu, Yongxie Wang, Jingjun Liu, Guosheng Shao

  • Year: 2021

7. Nitrogen-Doped Vertical Graphene Nanosheets by High-Flux Plasma Enhanced Chemical Vapor Deposition as Efficient Oxygen Reduction Catalysts for Zn–Air Batteries

  • Authors: Zhiheng Wu, Yongshang Zhang, Lu Li, Yige Zhao, Yonglong Shen, Shaobin Wang, Guosheng Shao

  • Year: 2020

8. Adding Refractory 5d Transition Metal W into PtCo System: An Advanced Ternary Alloy for Efficient Oxygen Reduction Reaction

  • Authors: Yige Zhao et al.

  • Year: 2018

9. PDA-Assisted Formation of Ordered Intermetallic CoPt₃ Catalysts with Enhanced Oxygen Reduction Activity and Stability

  • Authors: Yige Zhao et al.

  • Year: 2018

10. Dependent Relationship between Quantitative Lattice Contraction and Enhanced Oxygen Reduction Activity over Pt–Cu Alloy Catalysts

  • Authors: Yige Zhao et al.

  • Year: 2017

Mohamed Saber | Energy | Best Researcher Award

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Mr. Mohamed Saber | Energy | Best Researcher Award

Lecturer Assistant from Zagazig University, Egypt

Mohammed Al-Desouky is a dedicated early-career researcher and civil hydraulic engineer currently serving as a Lecturer Assistant in the Department of Water and Water Structures Engineering at Zagazig University, Egypt. His academic and professional journey reflects a strong commitment to advancing sustainable hydraulic systems, energy harvesting technologies, and computational fluid dynamics (CFD) applications. Mohammed’s work integrates theoretical research with hands-on experimentation and simulation, making significant strides in optimizing hydraulic structures for renewable energy production. His notable contribution includes a publication in the high-impact journal Renewable Energy, where he introduced a novel design for pico-hydropower generation using Dethridge waterwheels. His work addresses real-world challenges in low-head energy generation systems and demonstrates both academic rigor and practical relevance. In addition to his academic responsibilities, he is actively engaged in professional engineering practices as a civil hydraulic engineer and co-founder of a construction company. Mohammed’s multidisciplinary expertise spans water resources engineering, structural analysis, fluid mechanics, and advanced CFD modeling. His diverse experience, technical proficiency, and innovative mindset position him as a valuable contributor to the fields of renewable energy and hydraulic engineering. While still early in his research career, he displays notable potential for future impact through expanded collaborations, further publications, and international academic engagement.

Professional Profile

Education

Mohammed Al-Desouky holds a Bachelor of Science (B.Sc.) degree in Civil Engineering from Zagazig University, Egypt, earned in 2019 with an outstanding academic record, graduating with an overall grade of “Excellent with Honor” (88.65%). His undergraduate studies provided a comprehensive foundation in structural mechanics, fluid dynamics, and water resources engineering. He is currently pursuing a Master of Science (M.Sc.) degree in Water and Water Structures Engineering at the same university, with an expected completion year of 2025. His master’s thesis, titled “Investigation of Energy Harvesting by Water Wheels at Low-head Heading up Structures,” reflects a focused research interest in renewable energy applications within hydraulic engineering. This work combines field experimentation with computational analysis to evaluate the feasibility and efficiency of waterwheel systems for small-scale hydropower generation. His educational journey is characterized by a strong integration of theory and practice, reinforced by involvement in laboratory work, project supervision, and engineering simulations. Mohammed’s academic progression demonstrates a clear trajectory toward research excellence and technical innovation in civil and environmental engineering. As he continues to expand his scholarly contributions through graduate research and peer-reviewed publications, his education equips him with the necessary skills to address global challenges in sustainable water infrastructure.

Professional Experience

Mohammed Al-Desouky has built a multifaceted professional background in academia, research, and engineering practice. Since December 2019, he has worked as a Lecturer Assistant in the Department of Water and Water Structures Engineering at Zagazig University. In this role, he supports the delivery of undergraduate courses and laboratory sessions in fluid mechanics, hydraulics, and water structures, while also supervising student projects and contributing to curriculum development. Concurrently, he serves as a Civil Hydraulic Engineer at the university’s Irrigation and Hydraulics Lab, conducting both experimental and computational research on flow behavior and hydraulic systems. Beyond academia, Mohammed has pursued various freelance roles. Between 2020 and 2021, he worked as a structural design freelancer, providing engineering solutions using SAP2000, ETABS, and SAFE. Since 2022, he has been engaged as a general contracting engineer, managing on-site construction, quality control, and stakeholder coordination. He also operates as a freelance CFD engineer, delivering fluid dynamics simulations and technical assessments using ANSYS Fluent and FLOW-3D. In addition, Mohammed co-founded CIVIC, a construction company specializing in design-build services and real estate. His experience across academic, research, and industry domains illustrates his versatility, leadership potential, and commitment to translating engineering theory into practical applications.

Research Interests

Mohammed Al-Desouky’s research interests lie at the intersection of civil engineering, hydraulics, and sustainable energy technologies. His primary focus is on the development and optimization of low-head hydropower systems, particularly the use of waterwheels in energy harvesting applications. Through his M.Sc. research, he explores the integration of traditional hydraulic structures with modern energy generation techniques to create efficient and eco-friendly solutions. This includes experimental investigations and computational modeling of flow behavior in open channels and water passage systems. His interest in Computational Fluid Dynamics (CFD) has led him to apply advanced simulation tools such as ANSYS Fluent and FLOW-3D to study fluid-structure interactions, energy dissipation, and turbine performance under varying hydraulic conditions. Mohammed is also interested in techno-economic assessments of renewable energy systems, aiming to ensure not only the technical feasibility but also the economic sustainability of engineering solutions. In addition, his work touches upon the structural analysis and design of civil infrastructure, with particular attention to how structural and hydraulic systems interact. He is motivated by the potential for interdisciplinary research to address global challenges in clean energy, water scarcity, and resilient infrastructure, and seeks to expand his contributions through international collaboration and high-impact publications.

Research Skills

Mohammed Al-Desouky possesses a comprehensive set of research skills that span theoretical analysis, computational modeling, and experimental evaluation. He is proficient in conducting Computational Fluid Dynamics (CFD) simulations using advanced platforms such as ANSYS Fluent and FLOW-3D. These tools allow him to analyze complex flow fields, pressure distributions, and energy conversion mechanisms within hydraulic structures. He is also skilled in 3D modeling for CFD pre-processing using AutoCAD 3D and SOLIDWORKS, enabling the creation of accurate geometrical inputs for simulation. In structural engineering, he is adept at using SAP2000, ETABS, SAFE, and CSI Column for load analysis, system modeling, and structural detailing. His research capabilities extend to numerical analysis and data interpretation, where he can derive velocity vectors, pressure contours, and turbulence profiles to assess fluid behavior. Mohammed is equally comfortable with physical experimentation, having worked extensively in hydraulic labs on open channel flow setups. He is experienced in technical report writing, academic presentations, and collaboration on multidisciplinary projects. His ability to bridge simulation with real-world engineering scenarios enhances the practical impact of his research. Combined with his knowledge of productivity tools like Microsoft Office and Adobe Photoshop, he is well-prepared to deliver high-quality research outcomes with technical precision.

Awards and Honors

Mohammed Al-Desouky has been recognized for his academic excellence and early contributions to engineering research. He graduated with honors from Zagazig University in 2019, earning a B.Sc. in Civil Engineering with an “Excellent with Honor” distinction, reflecting consistent academic performance throughout his undergraduate studies. His high GPA and class ranking earned him a teaching assistant position immediately after graduation, enabling him to contribute to both education and research activities within the university. Although still in the early stages of his professional and academic career, he has already secured a significant research publication in the prestigious Renewable Energy journal, which in itself represents a notable milestone and demonstrates peer-recognized research output. Additionally, his membership in the Egyptian Engineers Syndicate since 2024 reflects his professional standing within the engineering community in Egypt. While he has not yet accumulated a broad list of national or international awards, his current achievements highlight a trajectory of growing impact and recognition. His combination of academic excellence, publication success, and professional engagement position him well for future honors and research-based awards as his career develops. With continued output and wider visibility, he is poised to earn more distinguished recognition in the field of sustainable civil engineering.

Conclusion

Mohammed Al-Desouky exemplifies the profile of a promising early-career researcher in the field of civil and hydraulic engineering. With a strong foundation in both theoretical and applied aspects of engineering, he demonstrates a clear focus on integrating renewable energy concepts into water infrastructure systems. His work on pico-hydropower systems using waterwheels represents an innovative approach to sustainable energy generation, supported by robust CFD modeling and experimental validation. His publication in a reputable international journal signifies a high level of academic credibility, and his technical skill set equips him to tackle complex engineering problems. Beyond his research, Mohammed is active in teaching, lab supervision, and engineering consultancy, reflecting a well-rounded professional identity. Although his research output is still emerging, the quality and relevance of his work suggest significant future potential. Areas for further development include expanding his publication record, increasing international collaborations, and pursuing competitive research grants. With continued commitment and strategic engagement in the research community, Mohammed is well-positioned to become a leading figure in water and energy systems engineering. His current accomplishments serve as a strong foundation for long-term academic and professional success in addressing global sustainability challenges.

Publication Top Note

  1. Title: Techno-economic Assessment of the Dethridge Waterwheel under Sluice Gates in a Novel Design for Pico Hydropower Generation
    Journal: Renewable Energy
    Publication Date: August 2024
    Type: Journal Article
    DOI: 10.1016/j.renene.2024.121206
    ISSN: 0960-1481
    Authors: Mohamed Saber, Gamal Abdelall, Riham Ezzeldin, Ahmed Farouk AbdelGawad, Reda Ragab

 

Hu Fangyuan | Energy | Best Researcher Award

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Prof. Dr. Hu Fangyuan | Energy | Best Researcher Award

Professor from Dalian University of Technology, China

Dr. Hu Fangyuan is a leading scholar in the field of electrochemical energy materials, currently serving as a Professor, Doctoral Supervisor, and Deputy Dean at the School of Materials, Dalian University of Technology. Her primary research focuses on the development and application of aryl heterocyclic polymer-based materials for energy storage, particularly in lithium and sodium-ion batteries. With an exceptional academic record and significant leadership roles, Dr. Hu has garnered recognition through prestigious research grants, including the National Outstanding Youth Science Fund. Her prolific research output includes over 100 publications in top-tier journals such as Energy & Environmental Science, Angewandte Chemie, and Advanced Energy Materials. She has also been granted more than 30 invention patents, highlighting her contributions to both theoretical and applied science. Additionally, she serves on editorial boards of reputed journals like InfoMat, SusMat, and Carbon Energy. Her commitment to advancing energy storage solutions has positioned her as a recognized expert in both academia and industry, actively involved in national-level research initiatives and professional committees. Dr. Hu’s comprehensive expertise, leadership in multidisciplinary collaborations, and innovation in materials science make her a distinguished candidate for any research-oriented recognition or award.

Professional Profile

Education

Dr. Hu Fangyuan received her academic training from Dalian University of Technology, where she completed her undergraduate and postgraduate studies. Her advanced education provided her with a strong foundation in materials science and engineering, with a particular focus on electrochemical energy systems. Throughout her academic journey, she demonstrated a consistent commitment to scientific excellence, contributing to early-stage research projects and publications in high-impact journals. Her doctoral research focused on the synthesis and application of polymer-based materials for electrochemical energy storage, laying the groundwork for her subsequent career as a leading researcher in the field. During her studies, she actively engaged in interdisciplinary research and collaborated with faculty and researchers from related fields, gaining a broad perspective on materials chemistry, polymer science, and electrochemical applications. Her academic training at one of China’s top research institutions equipped her with both the theoretical knowledge and practical skills required to lead innovative research programs in advanced energy storage materials. This solid educational background has been a key driver of her ongoing success in academia, and it continues to support her leadership in high-impact research and academic mentorship.

Professional Experience

Dr. Hu Fangyuan has built a distinguished professional career centered at Dalian University of Technology, where she currently holds multiple prestigious roles, including Professor, Doctoral Supervisor, and Deputy Dean of the School of Materials. Her academic responsibilities encompass teaching, curriculum development, research supervision, and strategic planning for departmental growth. Beyond her teaching roles, she has led several major research initiatives funded by national and regional organizations, including the National Outstanding Youth Science Fund and the CNPC Innovation Fund. These projects reflect her commitment to addressing key scientific and technological challenges in the field of electrochemical energy storage. In addition to her university-based work, Dr. Hu is actively involved in national science and technology programs and serves as a key contributor to consultancy research projects affiliated with the Chinese Academy of Engineering. Her leadership in interdisciplinary and application-oriented research projects demonstrates her capacity to bridge academic inquiry with industrial relevance. Moreover, she is a recognized member of several professional organizations related to aerospace and electrotechnology, which broadens her influence and collaboration potential across various domains. Dr. Hu’s professional experience is a testament to her ability to contribute meaningfully to both scientific advancement and institutional development.

Research Interest

Dr. Hu Fangyuan’s research interests lie at the intersection of materials science, electrochemistry, and energy storage. Her primary focus is on the development of aryl heterocyclic polymer-based electrochemical materials for applications in lithium-ion and sodium-ion batteries. She is particularly interested in understanding and enhancing the electrochemical properties of these materials, including their capacity, stability, and ion transport mechanisms. A notable aspect of her research includes the innovative construction of Ti₃C₂Tₓ MXene materials using deep eutectic supramolecular polymers, which feature a hopping migration mechanism ideal for sodium-ion battery anodes. Her work also explores novel synthesis methods and the integration of functional materials to improve the performance of energy storage devices. In addition to fundamental studies, Dr. Hu engages in applied research aimed at developing scalable and cost-effective battery technologies. Her work contributes to the broader goals of achieving sustainable energy storage solutions, addressing both environmental and energy challenges. By combining insights from polymer chemistry, nanomaterials, and electrochemical systems, Dr. Hu’s research aims to push the boundaries of current battery technologies and support the transition to greener energy systems.

Research Skills

Dr. Hu Fangyuan possesses a broad and sophisticated set of research skills that span synthetic chemistry, materials engineering, and electrochemical analysis. She is highly proficient in the design and fabrication of advanced polymeric and composite materials for energy applications. Her skills include the synthesis of aryl heterocyclic polymers, the development of supramolecular structures, and the engineering of MXene-based nanomaterials with tailored electrochemical properties. Dr. Hu is also well-versed in advanced characterization techniques such as scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray diffraction (XRD), and various spectroscopy methods to analyze material morphology and chemical composition. Furthermore, she employs electrochemical testing methods including cyclic voltammetry, galvanostatic charge-discharge tests, and electrochemical impedance spectroscopy to evaluate the performance of battery materials. Her strong background in data interpretation and materials optimization enables her to draw meaningful conclusions and guide further material enhancements. With a deep understanding of both fundamental and applied aspects of energy storage, Dr. Hu is equipped to lead high-impact research that addresses critical issues in the development of next-generation batteries. Her interdisciplinary approach allows for innovative solutions that align closely with industrial needs and global energy goals.

Awards and Honors

Dr. Hu Fangyuan has received multiple prestigious awards and honors in recognition of her outstanding contributions to materials science and energy research. Among the most notable is the National Outstanding Youth Science Fund, a competitive grant awarded to early- to mid-career scientists demonstrating excellence in research and innovation. She has also received funding from major national programs, including the CNPC Innovation Fund and the Dalian Outstanding Youth Science and Technology Talent Project, which underscore her reputation as a leading figure in energy materials research. Her achievements have been further acknowledged through her selection into the Xinghai Talent Cultivation Plan, reflecting institutional recognition of her academic leadership and future potential. In addition to research-based awards, Dr. Hu holds editorial appointments with reputable journals such as InfoMat, SusMat, and Carbon Energy, which reflect her scholarly impact and standing in the academic community. Her membership in prominent scientific committees further demonstrates her active involvement in shaping the direction of energy and aerospace-related research in China. These honors collectively affirm Dr. Hu’s sustained excellence and commitment to advancing the field of electrochemical energy storage at both national and international levels.

Conclusion

Dr. Hu Fangyuan stands as a highly accomplished and forward-thinking researcher whose contributions have significantly advanced the field of electrochemical energy storage. Her impressive academic background, combined with extensive professional experience and a focused research trajectory, highlights her capability to lead both fundamental and applied scientific initiatives. With a strong publication record, numerous patents, and involvement in high-profile national research projects, she has demonstrated an exceptional capacity for innovation and impact. Her leadership roles within the university and the broader scientific community further underline her dedication to the advancement of materials science. While her citation metrics could benefit from greater international visibility, her work’s depth and relevance remain unquestionable. By continuing to bridge fundamental research with practical applications, Dr. Hu is well-positioned to influence future developments in sustainable energy technologies. Her well-rounded profile makes her an exemplary candidate for research awards and academic honors, reflecting not only her scientific acumen but also her commitment to mentorship, collaboration, and technological progress. In conclusion, Dr. Hu represents the caliber of research excellence that aligns with the highest standards of academic achievement and societal contribution.

Publications Top Notes

  1. Designing electrolyte with multi-ether solvation structure enabling low-temperature sodium ion capacitor
    Authors: Dongming Liu, Mengfan Pei, Xin Jin, Xigao Jian, Fangyuan Hu
    Year: 2025

  2. Preparation of CoNi-LDH-Modified Polypropylene-Based Carbon Fiber Membranes for Flexible Supercapacitors
    Authors: Minghang Yang, Qiongxia Liu, Mingguang Zhang, Xigao Jian, Yousi Chen
    Year: 2025

  3. Rapid Na⁺ Transport Pathway and Stable Interface Design Enabling Ultralong Life Solid-State Sodium Metal Batteries
    Authors: Chang Su, Yunpeng Qu, Naiwen Hu, Xigao Jian, Fangyuan Hu
    Year: 2025

  4. Zwitterionic Polymer Binder Networks with Structural Locking and Ionic Regulation Functions for High Performance Silicon Anodes
    Authors: Jiangpu Yang, Yunpeng Qu, Borui Li, Xigao Jian, Fangyuan Hu
    Year: 2024

  5. Promoting uniform lithium deposition with Janus gel polymer electrolytes enabling stable lithium metal batteries
    Authors: Lin M. Wang, Shugang Xu, Zihui Song, Xigao Jian, Fangyuan Hu
    Year: 2024
    Citations: 2

  6. Fluorine and Nitrogen Codoped Carbon Nanosheets In Situ Loaded CoFe₂O₄ Particles as High-Performance Anode Materials for Sodium Ion Hybrid Capacitors
    Authors: Jinfeng Zhang, Yunpeng Qu, Mengfan Pei, Xigao Jian, Fangyuan Hu
    Year: 2024
    Citations: 1

  7. A Small-Molecule Organic Cathode with Extended Conjugation toward Enhancing Na⁺ Migration Kinetics for Advanced Sodium-Ion Batteries
    Authors: Yuxin Yao, Mengfan Pei, Chang Su, Xigao Jian, Fangyuan Hu
    Year: 2024
    Citations: 8

  8. Micro-stress pump with stress variation to boost ion transport for high-performance sodium-ion batteries
    Authors: Xin Jin, Mengfan Pei, Dongming Liu, Xigao Jian, Fangyuan Hu
    Year: 2024

Chenxu Zhang | Energy | Best Researcher Award

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Dr. Chenxu Zhang | Energy | Best Researcher Award

Postdoctoral Fellow from Shenzhen University, China

Dr. Chenxu Zhang is a dedicated materials scientist specializing in electrocatalysis, particularly focusing on hydrogen evolution reactions (HER) and water splitting technologies. His academic journey encompasses a bachelor’s and master’s degree from Shijiazhuang Tiedao University, a Ph.D. from Jilin University, and postdoctoral research at Shenzhen University and the City University of Hong Kong. Dr. Zhang’s research emphasizes the development of advanced catalysts, including high-entropy alloys and pentlandite-based materials, aiming to enhance the efficiency and stability of HER processes. His contributions are evidenced by multiple publications in high-impact journals and several granted patents, reflecting his commitment to advancing sustainable energy solutions through innovative materials design.

Professional Profile

Education

Dr. Zhang commenced his academic pursuits with a Bachelor of Engineering in Materials Science and Engineering at Shijiazhuang Tiedao University (2012–2016). He continued at the same institution for his master’s degree in Material Engineering (2016–2019), where he investigated the photocatalytic properties of graphite phase carbon nitride-based catalysts. Pursuing further specialization, he obtained his Ph.D. in Material Physics and Chemistry from Jilin University (2019–2022), focusing on transition metal chalcogenide catalysts for hydrogen production via water electrolysis. Currently, he is engaged in postdoctoral research at Shenzhen University and the City University of Hong Kong, exploring high-entropy alloy-based porous structures for electrocatalytic water splitting.

Professional Experience

Dr. Zhang’s professional trajectory is marked by significant research engagements across esteemed institutions. During his doctoral studies at Jilin University, he delved into the synthesis and application of transition metal chalcogenides for HER. His postdoctoral tenure at Shenzhen University and the City University of Hong Kong involves designing high-entropy alloy-based porous materials to improve electrocatalytic water splitting efficiency. Throughout his career, Dr. Zhang has led and contributed to multiple research projects, demonstrating his ability to manage complex scientific inquiries and collaborate effectively within multidisciplinary teams.

Research Interests

Dr. Zhang’s research interests are centered on the development of advanced materials for energy conversion processes. He focuses on electrocatalysis, particularly the hydrogen evolution reaction, aiming to design catalysts that are both efficient and stable across various pH environments. His work involves exploring high-entropy alloys, pentlandite-based materials, and transition metal chalcogenides to enhance water splitting technologies. By integrating experimental techniques with theoretical insights, Dr. Zhang seeks to address the challenges in sustainable hydrogen production, contributing to the broader goal of clean energy advancement.

Research Skills

Dr. Zhang possesses a robust skill set in materials synthesis, characterization, and performance evaluation. He is proficient in fabricating nanostructured catalysts and employing techniques such as X-ray diffraction, electron microscopy, and electrochemical measurements to assess material properties. His expertise extends to designing experiments that elucidate the mechanisms underlying catalytic processes, enabling the optimization of material performance. Additionally, Dr. Zhang demonstrates strong capabilities in scientific writing and project management, facilitating the dissemination of research findings and the successful execution of research initiatives.

Awards and Honors

Throughout his academic and professional journey, Dr. Zhang has received numerous accolades recognizing his contributions to materials science. His honors include national scholarships, provincial awards for outstanding graduates, and multiple prizes in innovation and entrepreneurship competitions. Notably, he has been acknowledged for his leadership and academic excellence during his tenure at Jilin University. These awards reflect Dr. Zhang’s dedication to research excellence and his impact within the scientific community.

Conclusion

Dr. Chenxu Zhang exemplifies a researcher with a profound commitment to advancing materials science for energy applications. His comprehensive education, extensive research experience, and consistent recognition through awards underscore his qualifications for the Best Researcher Award. Dr. Zhang’s work addresses critical challenges in sustainable energy, and his ongoing contributions continue to influence the field of electrocatalysis. His profile reflects a trajectory of excellence and innovation, making him a deserving candidate for recognition in his domain.

Publications Top Notes

  • A high-entropy oxyhydroxide with a graded metal network structure for efficient and robust alkaline overall water splitting
    Authors: Chenxu Zhang, et al.
    Journal: Advanced Science, 2024, Article ID: 2406008

  • Highly conductive amorphous pentlandite anchored with ultrafine platinum nanoparticles for efficient pH‐universal hydrogen evolution reaction
    Authors: Chenxu Zhang#, Yanan Cui#, et al.
    Journal: Advanced Functional Materials, 2021, 31, 2105372

  • Structure-catalytic functionality of size-facet-performance in pentlandite nanoparticles
    Authors: Chenxu Zhang, et al.
    Journal: Journal of Energy Chemistry, 2023, 78, 438

  • Ruthenium nanoparticles/pentlandite composite for efficient and stable pH-universal hydrogen evolution reaction: The enhanced interfacial interaction
    Authors: Chenxu Zhang, et al.
    Journal: Small, 2024, 19, 2301721

  • Recent advances in pentlandites for electrochemical water splitting: A short review
    Authors: Chenxu Zhang, et al.
    Journal: Journal of Alloys and Compounds, 2020, 838, 155685

  • The charge transport double-channel structure facilitating Fe₅Ni₄S₈/Ni₃S₂ nanoarray for efficient and stable overall water splitting
    Authors: Yanan Cui#, Chenxu Zhang#, et al.
    Journal: Applied Surface Science, 2022, 604, 154473

 

Shukur Nasirov | Energy | Best Researcher Award

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Assoc. Prof. Dr. Shukur Nasirov | Energy | Best Researcher Award

Chief of Department at Azerbaijan State Oil and Industry University, Azerbaijan 

Shukur Nasirov is an Associate Professor and Head of the Energy Production Technologies Department at Azerbaijan State Oil and Industry University (ASOIU). Born on June 1, 1962, in Masis District, Armenian SSR, he is an expert in industrial thermal power engineering with over 30 years of academic and professional experience. His contributions span teaching, research, and leadership, and he has authored more than 100 scientific, educational, and methodological works, including 10 study guides and 3 textbooks. His research focuses on renewable energy, gas turbine technologies, and thermal power plants. Dr. Nasirov is also an active member of various academic and dissertation councils, highlighting his dedication to advancing education and research in energy technologies.

Professional Profile

Education

Dr. Nasirov graduated with honors in 1985 from the Azerbaijan Institute of Oil and Chemistry (now ASOIU), specializing in “Industrial Heat Power Engineering.” He later earned the degree of Candidate of Technical Sciences (equivalent to Ph.D.) with a thesis on the thermal properties of gasoline fractions in offshore oil fields of Azerbaijan. His academic foundation in heat engineering and industrial energy systems has shaped his career as a leading expert in the field, providing a strong base for his teaching and research endeavors.

Professional Experience

Since 1990, Dr. Nasirov has held several academic and research roles at ASOIU. Starting as a junior researcher, he progressed to senior researcher and associate professor, conducting classes at the undergraduate and graduate levels. In 2021, he was appointed Head of the Department of Energy Production Technologies. He also served as chairman of the Student Scientific Society and has been a member of ASOIU’s Academic and Scientific Councils since 2018. Dr. Nasirov has contributed to numerous industry-focused projects, including designing new steam boilers for ships and developing strategies for the energy sector, showcasing his blend of academic and practical expertise.

Research Interests

Dr. Nasirov’s research interests include industrial thermal power engineering, gas turbine technologies, renewable energy systems, thermal physical properties of petroleum products, and the intensification of heat exchange in oil refining equipment. His work addresses the challenges of improving efficiency and sustainability in energy production and refining processes. He is also deeply engaged in theoretical aspects of heating techniques, ensuring that his research contributes to both applied and foundational knowledge in the field.

Research Skills

Dr. Nasirov possesses a wide array of research skills, including the design and analysis of thermal power systems, optimization of heat exchange processes, and evaluation of thermal physical properties of petroleum products. His expertise in gas and steam turbines, as well as his ability to perfect turbine cycles, underscores his proficiency in advancing energy technologies. He is adept at mentoring students and conducting applied research that bridges academic knowledge with industrial applications, making him a leader in his field.

Awards and Honors

Dr. Nasirov’s achievements have been recognized with numerous awards, including the Jubilee Medal for the 100th anniversary of ASOIU in 2021. He has received grants for innovative projects such as the development of energy sector strategies and designing steam boilers for marine applications. His contributions to academic and industrial research have earned him respect and recognition as a key figure in energy technologies.

Conclusion

Dr. Shukur Nasirov is a distinguished academic and researcher whose work in energy technologies has significantly advanced the field of industrial thermal power engineering. With decades of experience, extensive scientific output, and leadership in academia, he has made notable contributions to teaching, research, and industrial projects. His dedication to innovation, coupled with his focus on training future energy professionals, positions him as a respected figure in the global energy research community.

Publication Top Notes

  1. Title: Hydrogen technologies: Optical properties of hydrogenated amorphous thin films for solar cells
    Authors: Najafov, B.A., Nasirov, S.N., Nasirov, S.N.
    Journal: International Journal of Hydrogen Energy
    Year: 2025
    Volume & Pages: 101, pp. 47–53
  2. Title: Production of thin-layer silicon alloys and their application in solar-hydrogen energy
    Authors: Najafov, B.A., Nasirov, S.N., Nasirov, S.N., Verdiyev, N.M.
    Journal: International Journal of Hydrogen Energy
    Year: 2025
    Volume & Pages: 99, pp. 926–938
  3. Title: HYDROGEN technologies for the manufacture of solar-hydrogen Energy objects
    Authors: Najafov, B.A., Nasirov, S.N., Neymetov, S.R.
    Journal: International Journal of Hydrogen Energy
    Year: 2025
    Volume & Pages: 99, pp. 328–339
  4. Title: Analysis of the Efficiency of the Bivalent Parallel Mode of Operation of Heat Pumps in an Individual Residential Building: A Study of the Operating Modes of the Heat Supply System
    Authors: Babayeva, S., Nasirov, S.
    Journal: Przeglad Elektrotechniczny
    Year: 2024
    Volume & Pages: (9), pp. 235–238

 

Andrii Hrubiak | Renewable Energy Sources | Best Researcher Award

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Dr. Andrii Hrubiak | Renewable Energy Sources | Best Researcher Award

Emeritus at Cornell University, School of Integrative Plant Science, United States.

Dr. Andrii Hrubiak is a distinguished Senior Researcher at the G. V. Kurdyumov Institute for Metal Physics of the NAS of Ukraine. With a PhD in Physical and Mathematical Sciences, his research specializes in the physics and chemistry of surfaces, focusing on nanostructured materials, high-capacity electrochemical energy storage, photocatalysis, and Mossbauer spectroscopy. His work involves developing functional nanomaterials for energy storage and conversion and enhancing photocatalytic efficiency. Dr. Hrubiak has earned multiple accolades, including scholarships from the President of Ukraine and the Verkhovna Rada of Ukraine Prize for Young Scientists. His research contributions are well-recognized through numerous publications and patents, underscoring his impact in advancing material science and technology. His expertise extends to optimizing synthesis methods and improving performance characteristics of electrochemical and photocatalytic systems, making him a leading figure in his field.

Profile

Education🎓

Dr. Andrii Hrubiak’s educational journey reflects a robust foundation in physical and mathematical sciences with a focus on materials science. He began his academic path at the Galician Secondary School, where he graduated with honors in 2007. Pursuing higher education, he enrolled in the Faculty of Physics and Technology at Vasyl Stefanyk Precarpathian National University, Ivano-Frankivsk, earning a Master’s degree in Physics in 2012. His dedication to the field continued through postgraduate studies at the same institution, where he specialized in the physics of colloidal systems from 2012 to 2015. Building on this, Dr. Hrubiak furthered his expertise by completing doctoral studies at the G. V. Kurdyumov Institute for Metal Physics of the National Academy of Sciences of Ukraine, focusing on applied physics and nanomaterials between 2020 and 2022. This rigorous educational background underpins his significant contributions to nanomaterials and energy storage systems.

Professional Experience 🏢

Dr. Andrii Hrubiak has a distinguished career at the G. V. Kurdyumov Institute for Metal Physics of the N.A.S. of Ukraine, where he has served as a Senior Researcher in the Laboratory of Magnetic Film Physics since 2016. His expertise lies in the physics and chemistry of surfaces, focusing on nanostructured materials, high-capacity electrochemical energy storage, and photocatalysis. Prior to this role, Dr. Hrubiak conducted significant research as a Junior Researcher at Vasyl Stefanyk Precarpathian National University, contributing to international projects on nanodispersed rutile and iron oxides. His career also includes experience with Horizon 2020 programs and various national research grants. Dr. Hrubiak’s work has earned him several prestigious awards, including the Verkhovna Rada of Ukraine Prize and Scholarships from the President of Ukraine, underscoring his impactful contributions to the field of applied physics and nanomaterials.

Environmental Health

Dr. Hrubiak’s work in photocatalysis contributes to environmental health by developing materials that can efficiently degrade organic pollutants. His research on titanium dioxide and iron oxide composites aims to address environmental contamination and improve air and water quality.

Research Interests 🔬

Dr. Andrii Hrubiak’s research interests are centered on the development and application of advanced nanomaterials with a focus on the physics and chemistry of surfaces. His work predominantly explores nanostructured materials, including high-capacity electrochemical energy storage and generation systems. Dr. Hrubiak is deeply engaged in photocatalysis and Mossbauer spectroscopy, aiming to enhance the performance of functional materials. His research involves optimizing sol-gel and hydrothermal synthesis methods to create mesoporous systems based on transition metal oxides and hydroxides. These materials are tailored for use as active photocatalysts and electrode components in energy storage devices. His investigations have led to significant findings, such as improved photocatalytic activity in anatase/brookite composites and enhanced capacitance in hybrid supercapacitors. Dr. Hrubiak’s work contributes to advancements in both energy technology and environmental remediation.

Award and Honors

Dr. Andrii Hrubiak has been recognized with several prestigious awards for his significant contributions to the field of physical and mathematical sciences. In 2023, he was honored with the Scholarship named after Academician B.E. Paton for young scientists of the National Academy of Sciences of Ukraine. His innovative research also earned him the Scholarship of the President of Ukraine for young scientists in 2020, reflecting his impactful work in nanomaterials and energy storage. Dr. Hrubiak was awarded the Verkhovna Rada of Ukraine Prize for Young Scientists in 2019 for his pioneering work on nanostructured electrodes. Additionally, he received multiple grants from the National Academy of Sciences of Ukraine and the President of Ukraine, underscoring his excellence in advancing scientific knowledge. His accomplishments are further highlighted by his international accolades, including grants for research conducted in the United States and China.

Research Skills

Dr. Andrii Hrubiak possesses a robust skill set in the field of nanostructured materials and electrochemical energy systems. His expertise encompasses the synthesis and characterization of advanced nanomaterials, particularly transition metal oxides and hydroxides, which are pivotal for energy storage and photocatalysis. He excels in employing sol-gel and hydrothermal methods to create materials with optimized structural and electrochemical properties. Dr. Hrubiak is proficient in techniques such as Mossbauer spectroscopy, which he uses to investigate material properties at a microscopic level. His skills extend to the development of innovative electrode materials and photocatalysts, where he has significantly contributed to enhancing the performance of energy storage devices and environmental remediation processes. His ability to integrate theoretical research with practical applications underscores his proficiency in advancing the field of materials science and energy technologies.

Conclusion

Dr. Andrii Hrubiak is a distinguished researcher whose work has made substantial contributions to the fields of nanomaterials, energy storage, and photocatalysis. His international collaborations, applied research, and numerous awards highlight his impact and recognition in the scientific community. His innovative approaches and dedication to advancing material science and environmental technologies make him a strong candidate for the Research for Best Researcher Award.

Publications Top Notes 📚
  1. Insight into the Slag Foaming Behavior Utilizing Biocoke as an Alternative Carbon Source in Electric Arc Furnace-Based Steel Production
    • Authors: Kieush, L., Schenk, J., Koveria, A., Hrubiak, A.
    • Year: 2024
  2. Biocoke Thermochemical Properties for Foamy Slag Formations in Electric Arc Furnace Steelmaking
    • Authors: Kieush, L., Schenk, J., Koveria, A., Hrubiak, A.
    • Year: 2024
  3. Structurally dependent electroconductivity properties of ultrafine composites α-FeOOH/α-Fe2O3
    • Authors: Hrubiak, A.B., Ostafiychuk, B.K., Gasiuk, M.I., Gasiuk, I.M., Bushkova, V.S.
    • Year: 2024
  4. Evaluation of Slag Foaming Behavior Using Renewable Carbon Sources in Electric Arc Furnace-Based Steel Production
    • Authors: Kieush, L., Schenk, J., Koveria, A., Hopfinger, H., Zheng, H.
    • Year: 2023
  5. Influence of machining duration of 0.8SiO2/ 0.2Al2O3 nanopowder on electrochemical characteristics of lithium power sources
    • Authors: Yavorskyi, Y.V., Hrubiak, A.B., Zaulychnyy, Y.V., Gun’ko, V.M., Dudka, O.I.
    • Year: 2023
  6. Utilization of Renewable Carbon in Electric Arc Furnace-Based Steel Production: Comparative Evaluation of Properties of Conventional and Non-Conventional Carbon-Bearing Sources
    • Authors: Kieush, L., Schenk, J., Koveria, A., Hrubiak, A., Hopfinger, H.
    • Year: 2023
  7. Influence of biocoke on iron ore sintering performance and strength properties of sinter
    • Authors: Kieush, L., Hrubiak, A., Koveria, A., Molchanov, L., Moklyak, V.
    • Year: 2022
  8. Electroconductive Properties of Carbon Biocomposites Formed by the Precipitation Method
    • Authors: Hrubiak, A.B., Moklyak, V.V., Yavorsky, Yu.V., Ivanichok, N.Ya., Ilnitsky, N.R.
    • Year: 2022
  9. Transformation of the electrical impedance spectra of biological tissues under the influence of destructive factors
    • Authors: Pryimak, T.V., Gasyuk, I.M., Grubyak, A.V., Chervinko, D.M.
    • Year: 2022
  10. Structurally dependent electrochemical properties of ultrafine superparamagnetic ‘core/shell’ γ-Fe2O3/defective α-Fe2O3 composites in hybrid supercapacitors
    • Authors: Bazaluk, O., Hrubiak, A., Moklyak, V., Lozynskyi, V., Fedorov, S.
    • Year: 2021