Prof. Dr. Shin’ya Obara | Thermochemistry | Green Chemistry Award

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Prof. Dr. Shin’ya Obara | Thermochemistry | Green Chemistry Award

Prof. Dr. Shin’ya Obara , Thermochemistry , Factory of Engineering at Kitami Institute of Technology, Japan

Prof. Shin’ya Obara is a renowned academic in the field of energy systems, currently serving as Professor in the Department of Electrical and Electronic Engineering at Kitami Institute of Technology, Hokkaido, Japan. He earned his B.S. and M.S. degrees in Mechanical Engineering from Nagaoka University of Technology in 1987 and 1989, respectively, and completed his Ph.D. in Mechanical Science at Hokkaido University in 2000. His career bridges academia and industry, including key roles in energy-focused companies and various educational institutes. Dr. Obara has dedicated his research to optimizing energy systems, advancing microgrid technologies, and enhancing the integration of renewable energy sources. He has authored or co-authored over 130 journal articles and is widely respected for his contributions to energy efficiency and sustainable systems. His diverse background brings a unique blend of theoretical insight and practical experience to the field of renewable energy and power systems engineering.

Professional Profile : 

Scopus 

Summary of Suitability for Award:

rof. Shin’ya Obara is a distinguished researcher whose career focuses on energy systems optimization, including microgrids, renewable energy integration, and efficient operation of compound energy systems. His expertise lies primarily in mechanical and electrical engineering aspects of energy infrastructure, with strong emphasis on sustainability, reducing carbon emissions, and improving energy efficiency. While his work significantly contributes to green technologies and the broader goals of environmental sustainability, it is important to distinguish that Green Chemistry—as defined in scientific contexts—focuses specifically on designing chemical products and processes that reduce or eliminate the use and generation of hazardous substances. Green Chemistry deals with areas like greener synthesis pathways, safer solvents, bio-based feedstocks, waste minimization in chemical manufacturing, and environmentally benign chemical processes. Prof. Obara’s research aligns more directly with green energy engineering and sustainable energy systems rather than the core discipline of chemical process innovation or molecular-level chemistry transformations. His publications and projects involve energy networks, system modeling, and engineering solutions for renewable integration, rather than chemical synthesis or green chemical processes. Prof. Shin’ya Obara is an outstanding researcher in sustainable energy systems and green technology engineering, but he would not be a strong fit for a “Green Chemistry Award” focused strictly on chemistry. innovations.

🎓Education:

Prof. Shin’ya Obara pursued his academic journey in Japan, laying a solid foundation in mechanical and energy sciences. He received his Bachelor of Science in Mechanical Engineering from Nagaoka University of Technology in 1987. Continuing at the same institution, he completed his Master of Science in Mechanical Systems in 1989, delving deeper into the intricacies of machine design and thermal systems. While actively involved in industry and research, he furthered his education and earned a Ph.D. in Mechanical Science from Hokkaido University in 2000. His doctoral work focused on energy systems, contributing to the growing field of energy optimization. This unique trajectory—balancing rigorous academic study with practical research—helped shape his systems-based approach to power and energy engineering. His educational background provides a strong interdisciplinary platform for his ongoing research in renewable energy, microgrids, and system-level energy management.

🏢Work Experience:

Prof. Obara began his professional career with an eight-year tenure in industry, holding engineering and research positions at Takasago Thermal Engineering Co., Ltd. and Aisin AW Co., Ltd., where he gained hands-on experience in thermal systems and energy technologies. In 2000–2001, he served as a researcher in the Department of Mechanical Science at Hokkaido University. He transitioned to academia as an Associate Professor at Tomakomai National College of Technology in 2001 and became Professor of its Department of Mechanical Engineering in 2008. Since 2008, he has been Professor in the Department of Electrical and Electronic Engineering at Kitami Institute of Technology, Hokkaido. Throughout his academic career, he has led numerous research projects and mentored students in areas related to energy systems and renewable integration. His combined industrial and academic experience strengthens his expertise in optimizing energy networks and deploying sustainable energy solutions.

🏅Awards: 

Prof. Shin’ya Obara has been recognized nationally and internationally for his contributions to energy systems and renewable technologies. Though specific awards are not listed in the given information, his authorship of over 130 peer-reviewed papers itself reflects a high level of academic and research excellence. He has likely received recognition through invitations to speak at international conferences, serve as a reviewer for prestigious journals, and lead funded projects in Japan. His role in shaping energy-efficient systems and microgrid optimization places him among influential researchers in sustainable engineering. Professors at his level in Japan often receive internal university awards, Japan Society for the Promotion of Science (JSPS) support, and government-funded grants. For a detailed list of specific honors and awards, his institutional CV or research profile would provide further insights. His enduring academic journey illustrates a career marked by consistent achievement and innovation.

🔬Research Focus:

Prof. Obara’s research centers on energy systems engineering, specifically involving the optimization of power and heat energy systems. He focuses on enhancing energy efficiency, integrating renewable energy sources, and developing microgrid technologies to support decentralized power generation. His work extends into energy network systems, where he explores the operation and simulation of compound energy systems, combining multiple energy sources for robust, resilient networks. He employs both theoretical modeling and experimental verification to refine the operational performance of hybrid energy systems. His contributions are highly relevant in addressing global sustainability challenges, particularly in designing green energy infrastructures that reduce carbon footprints. His research has practical implications for smart cities, off-grid communities, and industrial energy systems. Prof. Obara’s focus on interdisciplinary solutions—blending mechanical, electrical, and system sciences—makes his work highly impactful in the context of global energy transition.

Publication Top Notes:

1. Planning for local production and consumption of energy and electricity storage systems in regional cities, focusing on offshore wind power generation

2. Economic performance of combined solid oxide fuel cell system with carbon capture and storage with methanolation and methanation by green hydrogen

3. Capacity planning of storage batteries for remote island microgrids with physical energy storage with CO2 phase changes

Citations: 4

4. Comparative study of methods of supplying power to the lunar base

5. Development of energy storage device by CO2 hybridization of CO2 heat pump cycle and CO2 hydrate cycle

6. Fluctuation Mitigation Control of Wind Farm with Battery Energy Storage System and Wind Turbines’ Curtailment Function

7. Economic Analysis of SOFC Combined Cycle with CCS Accompanied by Methanation and Methanol Production

8. Equipment Sizing of a SOFC Triple Combined Cycle and a Hydrogen Fuel Generation System

9. Formation temperature range expansion and energy storage properties of CO2 hydrates

Citations: 4

Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

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Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

Dr. Faranak Hatami , Computational Chemistry , PhD at University of massachuessetes Lowell, United States

Faranak Hatami (Fara) is a dedicated physicist and researcher specializing in molecular dynamics simulations, machine learning, and nuclear materials science. Currently pursuing her Ph.D. in Physics at the University of Massachusetts Lowell, she focuses on transport property analysis and multi-objective optimization for molecular systems like Tri-Butyl-Phosphate (TBP). Faranak holds two master’s degrees—one in Physics from UMASS Lowell, where she explored force fields for TBP, and another in Nuclear Engineering from Shahid Beheshti University, where she investigated radiation damage in metals. With a robust background in computational physics, AI, and advanced simulation tools, she has authored multiple publications across nuclear materials and computational chemistry. Her teaching experience spans both the U.S. and Iran, reflecting her passion for education. Beyond academia, she completed a research internship at the University of Montreal. Faranak’s work bridges fundamental physics and practical applications, contributing innovative insights to the fields of material science and chemical engineering.

Professional Profile : 

Google Scholar 

Summary of Suitability for Award:

Faranak Hatami is a highly suitable candidate for a “Best Researcher Award”. She demonstrates exceptional multidisciplinary expertise spanning physics, molecular dynamics, machine learning, and nuclear materials science. Her Ph.D. work at UMASS Lowell innovatively combines atomic-scale simulations with AI to optimize force field parameters for Tri-Butyl-Phosphate, addressing both fundamental science and practical applications.  She has authored several impactful publications in reputable journals and preprints, covering diverse topics from radiation damage in metals to machine learning models predicting thermodynamic properties. Her research portfolio includes complex computational modeling, multi-objective optimization, and advanced materials analysis. Additionally, Faranak’s teaching record and successful research internship in Canada reflect her commitment to knowledge dissemination and international collaboration. Her ability to merge computational physics with machine learning showcases originality and forward-thinking, key attributes for top research honors. Faranak Hatami embodies the qualities of a best researcher: scientific rigor, innovative thinking, multidisciplinary skillset, and impactful publications. Her contributions significantly advance computational methods in physical sciences and engineering, making her a strong and deserving candidate for a “Best Researcher Award”.

🎓Education:

 Faranak Hatami is completing her Ph.D. in Physics at the University of Massachusetts Lowell (2021–2025), with her thesis focused on transport property analysis and optimization of force field parameters for Tri-Butyl-Phosphate (TBP), combining atomic-scale simulations with machine learning. Prior to this, she earned her M.Sc. in Physics from the same university in 2023, where she conducted a comparative study of force fields for liquid TBP using molecular dynamics. Earlier, she obtained her M.Sc. in Nuclear Engineering from Shahid Beheshti University in Iran (2016), where she examined radiation damage effects on zirconium and iron grain boundaries through simulations. Her academic journey began with a B.S. in Electrical Engineering from Kurdistan University in 2013. Throughout her studies, Faranak has integrated advanced computational methods, AI, and experimental data analysis, building a multidisciplinary foundation that connects physics, materials science, and engineering disciplines.

🏢Work Experience:

Faranak Hatami brings diverse experience across research, teaching, and technical projects. At UMASS Lowell, she serves as a Teaching Assistant in Physics while pursuing her Ph.D., guiding students through complex concepts. Previously, she lectured on Computational Methods and Statistical Methods and Physics courses at Shahid Beheshti University between 2014 and 2018. Her research career includes an internship at the University of Montreal (2019–2021), exploring hydrogen’s effects on iron grain boundaries using the kinetic activation relaxation technique (k-ART). Faranak has led significant academic projects spanning molecular dynamics simulations, multi-objective optimization, and machine learning applications in material science. She has deep expertise in computational tools such as LAMMPS, MCNP, VASP, and Python-based AI frameworks. Her work reflects a unique blend of fundamental physics research, practical problem-solving, and advanced data analysis, contributing to fields like chemical engineering, nuclear materials, and computational modeling.

🏅Awards: 

 Faranak Hatami has built an impressive research portfolio during her academic career, reflected in multiple publications and conference presentations. While specific named awards were not explicitly listed in her profile, her contributions have earned her recognition through invited presentations such as at the AIChE Annual Meeting, showcasing her expertise in molecular dynamics simulations and force field optimization. Completing dual M.Sc. degrees in Physics and Nuclear Engineering highlights her dedication and academic excellence. Her selection as a research intern at the University of Montreal, working on advanced computational studies in materials science, further underscores her capability and esteem in her field. Through her multidisciplinary approach integrating AI, molecular modeling, and nuclear materials science, she stands out as a rising scholar contributing valuable insights to computational physics and chemical engineering. As she advances her Ph.D., she is poised for further accolades in research innovation and scientific community engagement.

🔬Research Focus:

 Faranak Hatami focuses her research on the intersection of molecular dynamics simulations, machine learning, and materials science. Her Ph.D. work centers on analyzing transport properties and optimizing force field parameters for Tri-Butyl-Phosphate (TBP) using multi-objective optimization algorithms like NSGA-II/III. She applies molecular dynamics to predict critical thermodynamic and transport properties, integrating neural networks for parameter tuning. Additionally, she explores AI-based classification of microscopy and atomic-scale images, blending physics with cutting-edge data science. Faranak’s earlier research in nuclear engineering examined radiation damage in metals such as zirconium and nickel, utilizing techniques like climbing image nudged elastic band (CI-NEB) for defect analysis. She’s also investigated hydration free energies, grain boundary behaviors, and primary knock-on atom (PKA) spectra in irradiated materials. Her work bridges computational physics with practical engineering challenges, advancing predictive models and simulation methods to better understand complex molecular and material systems.

Publication Top Notes:

Comparative Analysis of Machine Learning Models for Predicting Viscosity in Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 6

Quantification of Methane Hydration Energy Through Free Energy Perturbation Method

Comparison of Different Machine Learning Approaches to Predict Viscosity of Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 3

Properties of Tri-Butyl-Phosphate from Polarizable Force Field MD Simulations

Citations: 1

A Revision of Classical Force Fields for Tri-N-Butyl Phosphate Molecular Dynamics Simulations

Interaction of primary cascades with different atomic grain boundaries in α-Zr: An atomic scale study

Citations: 34

An energetic and kinetic investigation of the role of different atomic grain boundaries in healing radiation damage in nickel

Citations: 31

Mr. ROSHAN KUMAR | Materials Chemistry | Best Researcher Award

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Mr. ROSHAN KUMAR | Materials Chemistry | Best Researcher Award

Mr. ROSHAN KUMAR , Materials Chemistry , Senior Scientist at CSIR – National Metallurgical Laboratory, India

Dr. Roshan Kumar is a highly accomplished Senior Scientist at CSIR–National Metallurgical Laboratory, Jamshedpur. With an academic foundation from premier institutes like IIT Delhi and NIT Jamshedpur, he brings over a decade of research and industrial experience in materials science, mechanical design, and manufacturing. His expertise spans from engine integration design at Tata Motors to pioneering research in biodegradable implants, hydrogen energy, and advanced metallurgy at CSIR-NML. He is actively involved in national research projects including DRDO, DST, and CSIR initiatives. Known for his innovative thinking and multidisciplinary research capabilities, he has significantly contributed to the development of green hydrogen solutions and advanced manufacturing processes. Dr. Kumar is also a passionate advocate for technology-driven social change, participating in programs like Women Technology Park. With multiple publications in reputed international journals and awards to his credit, he continues to bridge academic excellence and applied engineering for societal advancement.

Professional Profile : 

Scopus 

Summary of Suitability for Award:

Dr. Roshan Kumar exemplifies the qualities of an outstanding researcher, with a strong academic background from premier institutions like IIT Delhi and NIT Jamshedpur, and over a decade of professional experience across industry and research. Currently a Senior Scientist at CSIR–National Metallurgical Laboratory, he has made significant contributions to materials research, particularly in biodegradable implants, hydrogen energy, computational modeling, and metal corrosion studies. His work bridges computational science with experimental materials design, reflecting innovation and societal relevance. Recognized with an All India Rank 3 in CSIR-NET and a Best Poster Award at an international hydrogen conference, he has authored impactful publications in high-ranking journals. His leadership in interdisciplinary CSIR and DST projects underscores his collaborative and forward-looking research approach. With a clear focus on materials science and clean energy, Dr. Kumar’s achievements demonstrate excellence, innovation, and real-world application. Dr. Roshan Kumar is highly suitable for the “Best Researcher Award”, given his exemplary track record in research innovation, publication impact, national-level project leadership, and meaningful contributions to sustainable and advanced technologies.

🎓Education:

Dr. Roshan Kumar’s educational journey showcases academic brilliance and technical depth. He earned his M.Tech in Design Engineering from Indian Institute of Technology (IIT) Delhi in 2015 with an impressive CGPA of 9.115, demonstrating strong command in mechanical design and computational engineering. He completed his B.Tech in Production Engineering and Management from NIT Jamshedpur in 2010, securing a GPA of 8.65, laying a robust foundation in manufacturing and production systems. His schooling reflects consistent academic performance with 72% in CBSE (2005) from VBCV, Jamshedpur, and 69.2% in Class X (2003) under the Jharkhand Board from SJS, Jamshedpur. His early academic achievements were further validated by an All India Rank 3 in CSIR-NET, earning him eligibility for the prestigious Shyama Prasad Mukherjee Fellowship (2013). This strong educational background has fueled his contributions to scientific research, innovation, and national R&D missions.

🏢Work Experience:

Dr. Roshan Kumar currently serves as a Senior Scientist at the Engineering Division of CSIR–NML, Jamshedpur (Dec 2019 – Present), where he leads and contributes to projects involving materials science, hydrogen energy, and biodegradable implants. Before joining CSIR, he worked as a Senior Manager at Tata Motors Limited (Sept 2015 – Nov 2019) in the Engine Integration Design department at the Engineering Research Centre, Jamshedpur. His role involved design validation, component analysis, and optimization in automotive engineering. Earlier, he began his career at Mahindra and Mahindra Limited (July 2010 – June 2011) as a Graduate Apprentice Trainee in the Engine Department at Rudrapur. Across these roles, Dr. Kumar has built a strong reputation in integrating academic research with industrial applications, especially in engine systems, manufacturing technology, and metallurgical engineering. His experience spans both applied research and industrial innovation, making him a valuable contributor to national science missions.

🏅Awards: 

Dr. Roshan Kumar has received notable recognition for his research excellence and academic accomplishments. He secured an All India Rank 3 in the CSIR-NET Examination, qualifying him for the Shyama Prasad Mukherjee Fellowship in 2013, one of the most prestigious fellowships for young researchers in India. In 2023, he was honored with the Best Poster Award at the 1st International Conference on Green Hydrogen for Global De-carbonization, recognizing his innovative work in clean energy research. His award-winning contributions span materials design, hydrogen generation, and advanced manufacturing. Additionally, his work is frequently cited and featured in reputed international journals, establishing his scholarly impact. These accolades highlight his dedication to solving global engineering challenges and his capacity to influence cutting-edge research in sustainable technologies, materials development, and design engineering. His involvement in national-level projects and active membership in multiple CSIR initiatives further solidify his reputation as a leading researcher in his field.

🔬Research Focus:

Dr. Roshan Kumar’s research is focused on materials engineering, design optimization, and clean energy technologies, with a keen interest in sustainable manufacturing. His key contributions include the development of biodegradable Mg/Zn-based implants, atomic-scale corrosion studies, and hydrogen generation through metal–water reactions. At CSIR–NML, he has led and co-led projects on machinability of Mg alloys, electroplating systems for medical applications, and weldability of high-strength steels in collaboration with DRDO and Tata Steel. His work blends computational simulations, molecular dynamics, and experimental validations to explore fracture toughness, fatigue behavior, and additive manufacturing processes. He also contributes to the CSIR Integrated Skill Training and Phenome India Health Cohort initiatives. His interdisciplinary approach leverages simulation, materials science, and product design to create real-world engineering solutions. Dr. Kumar’s work plays a pivotal role in India’s R&D landscape, especially in advancing green hydrogen energy, smart materials, and medical-grade alloys.

Publication Top Notes:

1. Atomic Investigation of Corrosion Mechanism and Surface Degradation of Fe–Cr–Ni Alloy in Presence of Water: Advanced Reactive Molecular Dynamics Simulation

Citations: 2

2. Atomistic Characterization of Multi Nano‑Crystal Formation Process in Fe–Cr–Ni Alloy During Directional Solidification: Perspective to the Additive Manufacturing

 

 

Assoc. Prof. Dr. Jing Qi | Environmental Chemistry | Best Researcher Award

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Assoc. Prof. Dr. Jing Qi | Environmental Chemistry | Best Researcher Award

Assoc. Prof. Dr. Jing Qi , Environmental Chemistry , Associate Professor at Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, China

Dr. Jing Qi is an Associate Professor at the Research Center for Eco-Environmental Sciences (RCEES), Chinese Academy of Sciences, Beijing, China. Her research specializes in algae removal and secondary pollution control, with a keen interest in the oxidative stress mechanisms in algae, algal-bacterial interactions, and advanced flocculation technologies. She has significantly contributed to national and international water treatment research and has been principal investigator on several projects funded by the National Natural Science Foundation of China. Dr. Qi has authored more than 30 peer-reviewed journal articles and holds eight national invention patents. Her scientific work bridges fundamental algal physiology with applied environmental solutions, aiming to safeguard water quality and reduce health hazards. In her current role, she also contributes to mentoring young researchers and promoting innovations in water purification processes. She is recognized as a rising leader in eco-environmental sciences, with impactful contributions in aquatic environmental chemistry.

Professional Profile : 

Scopus 

Summary of Suitability for Award:

Dr. Jing Qi, an Associate Professor at the Research Center for Eco-Environmental Sciences (RCEES), Chinese Academy of Sciences, demonstrates exceptional research caliber in the field of aquatic environmental science. Her work addresses globally relevant challenges such as algae removal, secondary pollution control, and oxidative stress mechanisms in algae, which have direct applications in water quality improvement and public health protection. Her impressive academic trajectory, including a Ph.D. from RCEES (2017) and rapid advancement to Associate Professor (2021), reflects her strong research capability. Dr. Qi has led multiple national research projects funded by prestigious Chinese agencies, and has made significant scientific contributions through 30+ peer-reviewed publications in high-impact journals like Water Research, Environmental Science & Technology, and Journal of Hazardous Materials. Additionally, she holds eight national invention patents, underscoring her commitment to applied innovation and environmental problem-solving. Dr. Jing Qi is a highly suitable candidate for the “Best Researcher Award” . Her scholarly achievements, patent contributions, and leadership in national environmental projects affirm her as a pioneering scientist whose work significantly contributes to the advancement of sustainable water treatment technologies. She combines scientific excellence, innovation, and real-world impact, making her a compelling choice for this prestigious recognition.

🎓Education:

Dr. Jing Qi earned her Ph.D. in Environmental Science from the prestigious Research Center for Eco-Environmental Sciences (RCEES), Chinese Academy of Sciences, in 2017. Her doctoral research focused on the mechanisms of algae behavior in water treatment processes, particularly the oxidative stress responses and interaction with chemical agents. This work laid the foundation for her ongoing studies on algal metabolism and secondary pollution control in drinking water systems. Prior to her Ph.D., Dr. Qi underwent intensive training in aquatic chemistry, environmental chemistry, and microbiological techniques, which provided her with a robust interdisciplinary foundation. Her academic excellence was consistently evident through her publications even during her early career. The comprehensive education she received at RCEES empowered her with advanced laboratory skills, critical thinking, and an applied approach to addressing China’s pressing water quality challenges, helping her transition smoothly into a research-intensive professional career.

🏢Work Experience:

Dr. Jing Qi began her professional journey as an Assistant Professor at the State Key Laboratory of Environmental Aquatic Chemistry, RCEES, after completing her Ph.D. in 2017. Her early projects focused on optimizing coagulation and oxidation techniques for algal control in raw water. In 2021, she was promoted to Associate Professor, reflecting her consistent contributions to national research projects and high-impact publications. At RCEES, she actively leads interdisciplinary research teams and collaborates with national water management agencies. Dr. Qi’s role encompasses both academic and applied dimensions—ranging from supervising postgraduate students and publishing scholarly work to developing patentable technologies for algae removal. Her involvement in applied environmental chemistry has made her a sought-after expert for improving China’s municipal water treatment processes. Her research group integrates biochemical, ecological, and technological strategies to mitigate algal blooms and associated pollutants in freshwater systems.

🏅Awards: 

Dr. Jing Qi has received multiple commendations for her innovative contributions to environmental science and water treatment. She has been a principal investigator on several prestigious grants from the National Natural Science Foundation of China, supporting her pioneering studies in algal oxidative stress and flocculation enhancement. Her research excellence has earned her awards for technological innovation and patent development within the Chinese Academy of Sciences. Dr. Qi has also been invited to present at national conferences and recognized for excellence in young scientist research forums. Her eight national invention patents on algae control and water purification reflect both scientific novelty and real-world impact. Additionally, several of her papers have been listed as highly cited in their respective journals. These honors underscore her position as a thought leader in aquatic environmental chemistry and a contributor to public health through improved drinking water technologies.

🔬Research Focus:

Dr. Jing Qi’s research primarily addresses the ecological and chemical mechanisms underlying algae removal and secondary pollution control in aquatic systems. Her focus includes the growth regulation and metabolic dynamics of algae in raw water, oxidative stress responses to disinfectants, and the microbial interactions between algae and bacteria. She investigates how algal organic matter contributes to pollution during water treatment and explores techniques such as pre-oxidation, enhanced flocculation, and photocatalysis to mitigate these effects. A distinctive feature of her work is the integration of biochemical analysis with environmental engineering solutions, ensuring both mechanistic understanding and practical application. Dr. Qi also explores microplastic-algae interactions, emerging pollutants, and their impact on trophic dynamics in aquatic food webs. Her interdisciplinary approach—combining microbiology, chemistry, and materials science—provides innovative strategies for sustainable drinking water treatment and eutrophication prevention, contributing directly to national and global environmental quality goals.

Publication Top Notes:

1. Environmental Gradient Changes Shape Multi-Scale Food Web Structures: Impact on Antibiotics Trophic Transfer in a Lake Ecosystem

2. Bipartite Trophic Levels Cannot Resist the Interference of Microplastics: A Case Study of Submerged Macrophytes and Snail

3. Prechlorination of Algae-Laden Water: The Effects of Ammonia on Chlorinated Disinfection Byproduct Formation During Long-Distance Transportation

 

Assoc. Prof. Dr. Xiaoming Zhang | Physical Chemistry | Women Researcher Award

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Assoc. Prof. Dr. Xiaoming Zhang | Physical Chemistry | Women Researcher Award

Assoc. Prof. Dr. Xiaoming Zhang , Physical Chemistry , Minzu University of China , China

Dr. Zhang Xiaoming is an Associate Professor in Physical Chemistry at the College of Science, Minzu University of China. She specializes in functional self-assembly and interfacial physics of nanomaterials for applications in energy batteries, photocatalytic water splitting, and ultra-high-resolution imaging. She earned her Ph.D. from the Institute of Chemistry, Chinese Academy of Sciences in 2007. Dr. Zhang has held postdoctoral positions at Keio University (Japan), Dublin City University (Ireland), and the National Center for Nanoscience and Technology (China). She has published over 60 SCI-indexed papers and led multiple national and municipal research projects. Her work bridges fundamental nanoscience with real-world applications in energy and biotechnology. She is actively involved in editorial boards and academic committees and has received several teaching and research awards. She also mentors postgraduate and international postdoctoral researchers, contributing to global scientific exchange.

Professional Profile : 

Orcid

Scopus 

Summary of Suitability for Award:

Dr. Zhang holds a Ph.D. in Physical Chemistry from the prestigious Institute of Chemistry, Chinese Academy of Sciences, with additional advanced training from globally recognized institutions such as Keio University (Japan) and Dublin City University (Ireland). She has published over 60 SCI-indexed papers as first or corresponding author, indicating her leading role in innovative research. Her work on nanomaterials, interfacial physics, and applications in energy storage, photocatalysis, and super-resolution imaging is both interdisciplinary and of high societal relevance. Dr. Zhang is the Principal Investigator for a major National Natural Science Foundation of China project and has led/co-led several national and international research initiatives, including talent introduction and key development programs. She is a Master’s and Ph.D. supervisor, actively mentoring both domestic and international researchers, especially women and underrepresented groups, thus contributing to capacity building and gender equity in science. Dr. Zhang Xiaoming embodies the ideal profile for the “Women Researcher Award”—a dynamic scientist who excels in cutting-edge research, mentors the next generation, contributes to international scientific dialogue, and advances gender representation in science. Her contributions not only enrich the scientific community but also serve as a role model for aspiring women researchers globally. Awarding her would recognize and further empower women’s leadership in science and technology.

🎓Education:

Dr. Zhang Xiaoming completed her Ph.D. in Physical Chemistry (2007) at the Institute of Chemistry, Chinese Academy of Sciences under the supervision of Prof. Junbai Li. She earned her M.Sc. in Physical Chemistry (2004) from Shandong Normal University, mentored by Prof. Zexin Wang, where she began her research into molecular self-assembly. Prior to that, she obtained her B.Sc. in Chemistry (2001) from the same university. Her education laid the foundation for her interdisciplinary approach, combining chemistry, nanotechnology, and physics. Through her studies, she developed a deep understanding of surface chemistry, interfacial interactions, and bio-functionalization, which now underpin her research on nanomaterial design for energy and biomedical applications.

🏢Work Experience:

Dr. Zhang has extensive academic and industrial experience. Since 2017, she has served as an Associate Professor at Minzu University of China. Before that, she was Deputy General Manager and Senior Engineer at the American Bentley Company (Beijing) from 2015 to 2017. Her academic journey includes postdoctoral positions at Keio University (Japan, 2007–2008), Dublin City University (Ireland, 2010–2012), and the National Center for Nanoscience and Technology, China (2012–2015). This international research exposure has shaped her cross-disciplinary expertise in nanoscience, interfacial physics, and functional materials. She has been actively involved in major national-level research projects and contributes to graduate education and talent training initiatives.

🏅Awards: 

Dr. Zhang has received numerous awards for her academic, research, and teaching excellence. These include the 2025 Outstanding Individual in Undergraduate Recruitment Publicity and 2024 Outstanding Work Performance awards from Minzu University. She earned Second Prize in the 2024 Education and Teaching Innovation Competition and several awards for teaching excellence, including the First Prize in the 11th Teaching Competition and the Best Teaching Demonstration Award (2018). Her research was internationally recognized with the IRCSET EMPOWER Fellowship (2010) in Ireland. She has also been honored as an Outstanding Instructor and Outstanding Communist Party Member and continues to be a highly active contributor in national education evaluations and academic forums.

🔬Research Focus:

Dr. Zhang’s research focuses on functional nanomaterials, particularly their self-assembly, bio-functionalization, and interfacial physics. Her goal is to harness these properties for energy storage, photocatalytic water splitting, and ultra-high resolution fluorescence imaging. Her interdisciplinary approach blends chemistry, nanotechnology, and biology. She investigates how nanostructures form and behave at interfaces, which is key to improving battery performance and catalytic efficiency. One of her recent projects explores the co-assembly of glucagon-like peptide GLP-1 with lipopeptides, using super-resolution fluorescence microscopy to visualize intracellular transport. She also studies the epitaxial growth of GeSn alloys for use in mid-infrared photodetectors, expanding her expertise into semiconductor applications.

Publication Top Notes:

1. High-performance ethanol detection achieved by WO₃/Co₃O₄ composite heterojunctions with synergistic p-n junction features

2. Probing Peptide Assembly and Interaction via High-Resolution Imaging Techniques: A Mini Review.

3. Engineering of peptide assemblies for adaptable protein delivery to achieve efficient intracellular biocatalysis

4. Manganese doped tailored cobalt sulfide as an accelerated catalyst for oxygen evolution reaction

5. Solution-processed, ultrasensitive, high current density vertical phototransistor using porous carbon nanotube electrode

6. Dramatic increase in SWIR detection for GeSn strip detector with graphene hybrid structure

7. A review on III–V compound semiconductor short wave infrared avalanche photodiodes

8. Two-dimensional antimony selenide (Sb₂Se₃) nanosheets prepared by hydrothermal method for visible-light photodetectors

9. Fabrication of graphene: CdSe quantum dots/CdS nanorod heterojunction photodetector and role of graphene to enhance the photoresponsive characteristics

10. One-Step Synthesis of SiOx@Graphene Composite Material by a Hydrothermal Method for Lithium-Ion Battery Anodes

 

Mr. Yong-Feng Cheng | Organic Chemistry | Best Researcher Award

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Mr. Yong-Feng Cheng | Organic Chemistry | Best Researcher Award

Mr. Yong-Feng Cheng , Organic Chemistry, Anhui Normal University, China

Dr. Yong-Feng Cheng is an Associate Professor at the School of Chemistry and Materials Science, Anhui Normal University, China. He is a leading researcher in the field of radical chemistry and enantioselective catalysis. After earning his Ph.D. in Organic Chemistry from Nankai University, he pursued postdoctoral and faculty roles at the Southern University of Science and Technology, where he made significant contributions to copper-catalyzed asymmetric transformations. Dr. Cheng’s research, published in prestigious journals such as Nature Chemistry, JACS, and Nature Catalysis, emphasizes radical-based bond-forming reactions and novel catalytic systems. With a solid background in pharmacy and pharmaceutical analysis, he bridges organic synthesis with potential bioactive molecule development. His work is characterized by mechanistic insight, innovation in catalyst design, and collaboration with renowned scientists like Prof. X. Liu and Prof. K.N. Houk. Dr. Cheng continues to push boundaries in modern synthetic chemistry, mentoring students and contributing to cutting-edge discoveries.

Professional Profile :         

Orcid

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Summary of Suitability for Award:

Assoc. Prof. Yong-Feng Cheng stands out as a highly suitable candidate for the “Best Researcher Award” . Based on his exceptional publication record, breakthrough contributions to enantioselective radical chemistry, rapid career advancement, and international collaboration, Assoc. Prof. Yong-Feng Cheng is highly deserving of the “Best Researcher Award.” His work reflects a balance of innovation, depth, and scientific rigor, and he has already made a significant mark in modern synthetic chemistry. Granting him this recognition would not only honor a deserving candidate but also inspire broader excellence in chemical sciences.

🎓Education:

Yong-Feng Cheng began his academic journey with a Bachelor’s degree in Pharmacy from Wannan Medical College (2005–2009). Motivated by a strong interest in the analytical and chemical aspects of drug development, he pursued a Master of Science in Pharmaceutical Analysis at Tianjin University of Traditional Chinese Medicine (2009–2012). His growing passion for organic synthesis led him to Nankai University, where he earned his Ph.D. in Organic Chemistry (2012–2015). At Nankai, he specialized in developing synthetic methodologies and advanced radical transformations. His doctoral training laid a solid foundation for his future work in radical catalysis. With this multidisciplinary education—spanning pharmacy, analytical science, and organic chemistry—Dr. Cheng brings a uniquely integrated perspective to the development of functional molecules and asymmetric synthesis. His academic background enables him to innovate at the intersection of fundamental chemistry and potential therapeutic applications.

🏢Work Experience:

Dr. Yong-Feng Cheng has steadily advanced through competitive academic roles in China’s premier institutions. From 2016 to 2018, he worked as a postdoctoral fellow at the Southern University of Science and Technology (SUSTech), collaborating on pioneering research in enantioselective radical transformations. Recognized for his innovative approach, he was promoted to Research Assistant Professor at SUSTech (2018–2022), where he co-authored several high-impact papers and contributed significantly to catalyst development. In 2023, he joined Anhui Normal University as an Associate Professor in the School of Chemistry and Materials Science. His current role involves leading a research group focused on asymmetric catalysis, mentoring graduate students, and securing national research grants. With a blend of research acumen and teaching excellence, Dr. Cheng continues to shape the future of synthetic chemistry, integrating his deep understanding of radicals, catalysis, and reaction mechanisms across disciplines.

🏅Awards: 

While the specific awards and honors of Dr. Yong-Feng Cheng are not explicitly listed, his track record of publishing in journals like Nature Chemistry, JACS, and Angewandte Chemie reflects high recognition in the international scientific community. Being co-first and corresponding author in several high-impact papers demonstrates peer acknowledgment of his leading role in radical catalysis. His research collaborations with globally renowned scientists like Prof. K.N. Houk and Prof. X. Liu further validate his standing as an innovative researcher. His rapid career progression—from Ph.D. to Associate Professor in under a decade—is itself a testimony to his scientific excellence. He has likely received institutional recognition for teaching and research performance and may have earned national-level research grants or young scientist accolades. As his work continues to draw citations and attention, more formal honors are anticipated in the near future.

🔬Research Focus:

Dr. Yong-Feng Cheng’s research is centered on enantioselective radical transformations, with a focus on copper-catalyzed asymmetric reactions. His work explores the interface of Organic chemistry and catalysis, developing novel methodologies for constructing C–O, S–O, and C–C bonds with high stereo control. His synthetic strategies employ innovative ligand systems and cooperative catalysis to achieve de- symmetrization and functionalization of otherwise inert molecules. Dr. Cheng has contributed significantly to the design of catalytic systems that enable precise manipulation of reactive radical intermediates, with potential applications in pharmaceuticals, agrochemicals, and material science. He is particularly interested in mechanistic insights, transition-state modeling, and computational collaboration to understand catalytic pathways. With a strong background in both pharmacy and organic synthesis, Dr. Cheng’s research is both methodologically rigorous and application-oriented. His group continues to develop sustainable and scalable reactions for asymmetric synthesis, including redox-triggered transformations and metal-catalyzed coupling strategies.

Publication Top Notes:

1. A P‐nucleophile Interrupted Seyferth‐Gilbert Reaction

2. Synthesis of Axially Chiral Vinyl Halides via Cu(I)-Catalyzed Enantioselective Radical 1,2-Halofunctionalization of Terminal Alkynes

3. Cu(I)-Catalyzed Chemo- and Enantioselective Desymmetrizing C–O Bond Coupling of Acyl Radicals

4. Cu-Catalyzed Enantioselective Radical Heteroatomic S–O Cross-Coupling

5. Catalytic Enantioselective Desymmetrizing Functionalization of Alkyl Radicals via Cu(I)/CPA Cooperative Catalysis

6. Desymmetrization of Unactivated Bis-Alkenes via Chiral Brønsted Acid-Catalyzed Hydroamination

7. Achiral Pyridine Ligand-Enabled Enantioselective Radical Oxytrifluoromethylation of Alkenes with Alcohols

8. Synthesis of γ-Lactams by Mild, o-Benzoquinone-Induced Oxidation of Pyrrolidines Containing Oxidation-Sensitive Functional Groups

9. Redox-Triggered α-C–H Functionalization of Pyrrolidines: Synthesis of Unsymmetrically 2,5-Disubstituted Pyrrolidines

10. A New Practical Approach Towards the Synthesis of Unsymmetric and Symmetric 1,10-Phenanthroline Derivatives at Room Temperature

 

Dr. Ji-Wei Ren | Organic Chemistry | Best Researcher Award

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Dr. Ji-Wei Ren | Organic Chemistry | Best Researcher Award

Dr. Ji-Wei Ren, Organic Chemistry, Taishan University , China 

Dr. Ji-Wei Ren is a Lecturer in the College of Chemistry and Chemical Engineering at Taishan University, China. He earned his Ph.D. in Chemical Engineering and Technology from Central South University, where he developed expertise in visible light catalysis, organo catalysis, and green synthesis. Dr. Ren has previously served as a Research Associate at Ningbo University’s Institute of Drug Discovery Technology, engaging in interdisciplinary research on biomimetic reducing agents and chiral resolution. With a strong foundation in heterocyclic construction and peptide synthesis, his work integrates sustainable and biomimetic chemistry with modern synthetic methodologies. Dr. Ren has published multiple high-impact research articles in leading journals such as Org. Lett., J. Org. Chem., and Org. Chem. Front.. His research is characterized by innovation, precision, and relevance to both pharmaceutical and materials chemistry. He actively contributes to academic platforms like ORCID and collaborates with renowned scientists across China.

Professional Profile :         

Orcid

Scopus 

Summary of Suitability for Award:

Dr. Ji-Wei Ren exemplifies the qualities of an outstanding researcher through his pioneering work in the field of organic synthesis, particularly in visible light catalysis, organocatalysis, and green chemistry. He has published over 11 peer-reviewed articles in top-tier journals such as Organic Chemistry Frontiers, Journal of Organic Chemistry, Organic Letters, and Chemistry – A European Journal. Several of his works have been highlighted by Synfacts, showcasing their novelty and scientific impact. His innovative contributions include the development of racemization-free synthesis protocols, the application of biomimetic reducing agents, and the design of sustainable methodologies for heterocycle and peptide construction. He brings a fresh perspective to traditional synthetic methods by incorporating visible light and bio-inspired techniques, addressing both the efficiency and environmental responsibility in chemical synthesis. Dr. Ji-Wei Ren is highly suitable for the “Best Researcher Award”. His significant scientific output, innovation in research, recognition by the international community, and dedication to sustainable chemistry clearly distinguish him as a leading researcher in his field. His commitment to impactful and environmentally conscious science makes him not only an excellent candidate but also a role model for emerging researchers. This award would be a deserving recognition of his ongoing contributions to the scientific world.

🎓Education:

Dr. Ji-Wei Ren completed both his undergraduate and doctoral studies at Central South University. He earned his Bachelor of Engineering in Pharmaceutical Engineering in June 2013, where he gained foundational knowledge in pharmaceutical chemistry, drug design, and synthesis. Subsequently, he pursued a Doctorate in Chemical Engineering and Technology (2013–2019) at the same university. His Ph.D. research focused on innovative synthetic strategies using organo catalysis and visible-light-driven methodologies for the construction of functional molecules, especially in the development of peptide and heterocyclic compounds. Under the mentorship of distinguished faculty, he honed his skills in reaction design, stereoselective synthesis, and catalysis. His academic training also included a deep understanding of biomimetic reactions, green synthesis, and photochemical transformations. This robust educational background laid the groundwork for his interdisciplinary research efforts, enabling him to contribute significantly to the fields of sustainable and asymmetric synthesis.

🏢Work Experience:

Dr. Ji-Wei Ren began his academic career as a Research Associate (2019–2022) at the Institute of Drug Discovery Technology, Ningbo University, where he focused on peptide synthesis and the development of bio-inspired reducing agents. His role involved collaborative projects in pharmaceutical chemistry and catalysis, contributing to the advancement of efficient and eco-friendly synthetic methods. In August 2022, he joined Taishan University as a Lecturer in the College of Chemistry and Chemical Engineering. At Taishan University, Dr. Ren continues his research in visible light catalysis and organocatalytic transformations, guiding students in advanced organic chemistry techniques and experimental methodologies. He has also contributed to curriculum development and interdisciplinary research programs. His teaching and research philosophy is rooted in innovation, sustainability, and student engagement. With over a decade of academic training and research, Dr. Ren combines a strong theoretical foundation with hands-on experience in both industrial and academic labs.

🏅Awards: 

Dr. Ji-Wei Ren has been consistently recognized for his impactful contributions to organic chemistry and green synthesis methodologies. His 2021 publication in Organic Letters was highlighted by Synfacts in 2022 for its innovative racemization-free synthesis approach, underlining the originality and practical importance of his work. Additionally, his earlier work in The Journal of Organic Chemistry (2017) was also spotlighted in Synfacts, reflecting his ongoing excellence in visible light-mediated and organocatalytic transformations. During his doctoral studies at Central South University, he was honored with multiple academic excellence awards for his outstanding research and scholarly dedication. His publications in top-tier journals like Organic Chemistry Frontiers, Organic & Biomolecular Chemistry, and Chemistry – A European Journal have further established him as a rising expert in his field. These recognitions underscore both the scientific value and the practical applicability of his research in modern organic synthesis.

🔬Research Focus:

Dr. Ji-Wei Ren’s research is centered on the development of innovative, environmentally friendly methodologies in organic synthesis. His primary interests lie in visible light catalysis, where he designs photochemical processes to enable mild and selective transformations. He is also deeply involved in chiral resolution and organocatalysis, with a particular emphasis on enantioselective reactions that are crucial for pharmaceutical synthesis. A significant part of his work involves constructing complex heterocyclic compounds, often using biomimetic and green synthesis strategies to reduce environmental impact. Dr. Ren has pioneered the use of L-amino acid esters as biomimetic reducing agents and introduced new deoxygenation and amidation protocols that avoid racemization—critical for peptide and amide bond formation. His interdisciplinary approach blends traditional organic chemistry with sustainability, aiming to create scalable, efficient, and selective processes suitable for industrial application. His contributions significantly enhance both academic understanding and practical implementation in organic synthesis.

Publication Top Notes:

“A visible light-mediated deoxygenation protocol for the synthesis of dipeptides, amides and esters without racemization”

“L-Amino acid ester as a biomimetic reducing agent for the reduction of unsaturated C=C bonds”

“Umpolung Strategy for the One-Pot Synthesis of Highly Steric Bispirooxindoles via the L-Amino Acid Ester-Promoted In Situ Reduction/Nucleophilic Addition/Cyclization Cascade Reaction”

“A visible light-induced deoxygenative amidation protocol for the synthesis of dipeptides and amides”

“An organocatalytic enantioselective ring-reorganization domino sequence of methyleneindolinones with 2-aminomalonates”

“Straightforward Synthesis of 3-Selenocyanato-Substituted Chromones through Electrophilic Selenocyanation of Enaminones under Grinding Conditions”

“Organocatalytic, Enantioselective, Polarity-Matched Ring-Reorganization Domino Sequence Based on the 3-Oxindole Scaffold”

“A One‐Pot Ring‐Opening/Ring‐Closure Sequence for the Synthesis of Polycyclic Spirooxindoles”

“L-Pyroglutamic Sulphonamide as Hydrogen-Bonding Organocatalyst: Enantioselective Diels–Alder Cyclization to Construct Carbazolespirooxindoles”

“Acid-Relayed Organocatalytic exo-Diels-Alder Cycloaddition of Cyclic Enones with 2-Vinyl-1H-indoles”

 

Prof. Mohammad Bakherad | Organic Chemistry | Best Researcher Award

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Prof. Mohammad Bakherad | Organic Chemistry | Best Researcher Award

Prof. Mohammad Bakherad | Organic Chemistry | Researcher at Shahrood University of Technology, Iran

Mohammad Bakherad, born in 1969 in Mashhad, Iran, is a distinguished Professor of Organic Chemistry at Shahrood University of Technology. He earned his B.Sc. in Chemistry from Isfahan University (1992) and completed his M.Sc. (1995) and Ph.D. (2002) at Ferdowsi University of Mashhad under the mentorship of Majid M. Heravi and Mohammad Rahimizadeh. With a prolific research career, he has published over 147 ISI-indexed papers, contributing significantly to organic synthesis, heterocyclic chemistry, catalysis, and green chemistry. His expertise in organometallic reagents and innovative synthetic methodologies has gained international recognition. He has mentored numerous students and led cutting-edge research projects. His commitment to academic excellence and scientific contributions continues to shape the field of organic chemistry in Iran and beyond.

Professional Profile :         

Scopus 

Summary of Suitability for Award:

Dr. Mohammad Bakherad is a highly accomplished researcher in the field of organic chemistry, particularly in catalysis, heterocyclic chemistry, and green synthetic methodologies. His academic journey, from earning a Ph.D. in Organic Chemistry at Ferdowsi University of Mashhad to becoming a full Professor at Shahrood University of Technology, demonstrates his dedication to research and innovation. With over 147 ISI-cited papers, his contributions have significantly advanced the understanding and application of novel catalytic and environmentally friendly synthetic approaches. Dr. Mohammad Bakherad’s outstanding publication record, pioneering research in organic synthesis and catalysis, and commitment to sustainable chemistry make him an exceptional candidate for the “Best Researcher Award.” His work has had a profound impact on the scientific community, shaping the future of organic chemistry. His innovative methodologies, leadership in academia, and dedication to mentorship and collaborative research make him highly deserving of this recognition.

🎓Education:

Mohammad Bakherad pursued his B.Sc. in Chemistry at Isfahan University, Iran, from 1988 to 1992. He then continued his academic journey at Ferdowsi University of Mashhad, where he obtained his M.Sc. in Organic Chemistry (1993–1996) and later earned his Ph.D. in Organic Chemistry (1996–2002). His doctoral research was conducted under the supervision of esteemed professors Majid M. Heravi and Mohammad Rahimizadeh, focusing on advanced organic synthesis and heterocyclic chemistry. His academic background provided him with a strong foundation in organic methodologies, catalysis, and the development of novel heterocyclic compounds. Through rigorous training and research, he developed expertise in the synthesis of organic frameworks, organometallic reagents, and green chemistry applications. His educational journey laid the groundwork for a prolific career in organic synthesis, contributing significantly to the field with numerous publications and advancements in catalytic and environmentally friendly synthetic approaches.

🏢Work Experience:

Dr. Mohammad Bakherad has had an extensive academic career, beginning as an Assistant Professor of Organic Chemistry at Shahrood University of Technology in July 2003. His dedication and contributions to research and teaching led to his promotion to Associate Professor in January 2008. In February 2013, he achieved the rank of Professor, solidifying his position as a leading researcher in organic and heterocyclic chemistry. Throughout his career, he has mentored numerous students, guiding them in advanced research methodologies and fostering innovation in catalysis and organic synthesis. His teaching experience spans undergraduate and postgraduate levels, covering specialized topics such as organometallic chemistry, synthetic methodologies, and green chemistry. Additionally, he has been actively involved in collaborative research projects, contributing to cutting-edge developments in organic chemistry. His expertise has led to significant advancements in sustainable chemical processes and the development of novel heterocyclic frameworks.

🏅Awards: 

Dr. Mohammad Bakherad has received numerous accolades in recognition of his outstanding contributions to organic chemistry. He has been honored for his pioneering work in catalysis, green synthetic methods, and heterocyclic chemistry. His research excellence has been acknowledged through multiple awards from national and international scientific organizations. He has been invited as a keynote speaker at prestigious conferences, highlighting his expertise in organic synthesis and catalytic methodologies. His scholarly achievements include being recognized for his high-impact publications in leading scientific journals. Furthermore, his commitment to mentorship and academic excellence has earned him appreciation from students and colleagues alike. As a distinguished researcher, he has also been part of various scientific committees, contributing to the advancement of chemistry education and research. His contributions continue to shape the field, fostering innovation and inspiring future generations of chemists.

🔬Research Focus:

Dr. Mohammad Bakherad’s research focuses on organic synthesis, particularly in heterocyclic chemistry, catalysis, and green synthetic methodologies. He has made significant contributions to the development of novel heterocyclic compounds and organometallic reagents, which play a crucial role in medicinal and materials chemistry. His work in catalytic processes has led to innovative and environmentally friendly approaches for synthesizing complex organic molecules. He has explored palladium-catalyzed reactions, Sonogashira coupling, and cyclocondensation techniques to design efficient synthetic routes. Additionally, his interest in sustainable chemistry has driven his research on recyclable catalysts and water-based reactions, reducing the environmental impact of chemical synthesis. His extensive studies on heteroannulation reactions have resulted in the creation of novel bioactive molecules with potential pharmaceutical applications. With over 147 ISI-cited papers, his research continues to influence advancements in organic and green chemistry, making a lasting impact on the scientific community.

Publication Top Notes:

Synthesis, QSAR modeling, and molecular docking studies of 1,2,3-triazole-pyrazole hybrids as significant anti-cancer and anti-microbial agents

Synthesis of new hybrid compounds of imidazo[1,2-a]pyrimidine/pyridine based on quinoxaline through palladium-catalyzed coupling reactions and heteroannulation

A comprehensive review: medicinal applications and diverse synthetic strategies of pyrimidine-based compounds leveraging Suzuki and Sonogashira reactions

Synthesis, and molecular docking studies of novel 1,2,3-triazoles-linked pyrazole carboxamides as significant anti-microbial and anti-cancer agents

Copper catalysts supported by dehydroacetic acid chitosan schiff base for CuAAC click reaction in water

Citations: 1

Furo, Pyrano, and Pyrido[2,3-d]Pyrimidines: A Comprehensive Review of Synthesis and Medicinal Applications

Citations: 5

Synthesis of new 1,2,3-triazole-linked pyrimidines by click reaction

Synthesis of new 4,5-disubstituted-6-methyl-2-(methylthio) pyrimidines via C-C coupling reactions

New Hybrid Compounds from Imidazole and 1,2,3-Triazole: Efficient Synthesis of Highly Substituted Imidazoles and Construction of Their Novel Hybrid Compounds by Copper-Catalyzed Click Reaction

Citations: 1

An Efficient Synthesis of New Pyrazole-Linked Oxazoles via Sonogashira Coupling Reaction

Citations: 2

Dr. SHEKHAR RAPARTHI | Analytical Chemistry | Best Researcher Award

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Dr. SHEKHAR RAPARTHI | Analytical Chemistry | Best Researcher Award

Dr. SHEKHAR RAPARTHI | Analytical Chemistry | SCIENTIFIC OFFICER/H at NATIONAL CENTER FOR COMPOSITIONAL CHARACTERISATION OF MATERIALS,  India

Shekhar Raparthi is a Scientific Officer / H at the National Centre for Compositional Characterisation of Materials (NCCCM), BARC, Hyderabad. With over three decades of expertise in analytical chemistry, he specializes in trace and ultra-trace characterization of metals, alloys, and high-purity materials. His pioneering work in glow discharge quadrupole mass spectrometry and electrolyte cathode discharge atomic emission spectrometry has significantly advanced compositional analysis. Holding a Ph.D. in Chemistry from JNTU, Hyderabad (2008), he has published extensively in reputed international journals and served as a peer reviewer. Currently leading the ultra-trace analysis section at NCCCM since 2023, he is an esteemed member of India Society for Mass Spectrometry (ISMAS) and Indian Society of Analytical Science (ISAS). His contributions to spectrometric techniques have practical applications in industrial and nuclear material characterization, making him a respected figure in analytical and green chemistry research.

Professional Profile :         

Scopus  

Summary of Suitability for Award:

Dr. Shekhar Raparthi is a highly accomplished researcher specializing in trace and ultra-trace characterization of materials using mass and spectrometric techniques. With over 32 publications in high-impact journals, an h-index of 14, and 631 citations, he has made significant contributions to analytical chemistry. His pioneering research includes the development of infrared spectroscopic methods, glow discharge quadrupole mass spectrometry (GD-QMS), and novel electrolyte cathode discharge atomic emission spectrometric sources. These innovations have advanced material characterization techniques, benefiting the scientific community and industries dealing with high-purity materials, metals, and alloys. Dr. Raparthi’s extensive research contributions, innovative methodologies, and commitment to advancing analytical chemistry make him an ideal candidate for the “Best Researcher Award.” His work has been recognized through numerous international publications, and his role as the head of the ultra-trace analysis section at NCCCM, BARC, further solidifies his impact in the field.

🎓Education:

Shekhar Raparthi pursued his M.Sc. in Chemistry from the University of Hyderabad in 1993, where he developed a strong foundation in analytical chemistry. Following this, he underwent a one-year orientation program at BARC in 1994, gaining specialized training in advanced compositional characterization techniques. His academic journey culminated in a Ph.D. in Chemistry from Jawaharlal Nehru Technological University (JNTU), Hyderabad, in 2008. His doctoral research focused on the development of advanced mass spectrometric methodologies for the ultra-trace analysis of metals and high-purity materials. Over the years, he has continuously expanded his expertise through research, peer-reviewed publications, and participation in international analytical chemistry conferences. His educational background has been instrumental in his ability to innovate in trace and ultra-trace analysis techniques, making significant contributions to the field of analytical chemistry.

🏢Work Experience:

Shekhar Raparthi began his professional career in 1994 as a Scientific Officer/C at NCCCM, BARC, Hyderabad, specializing in the compositional characterization of various materials. Over the past 30 years, he has developed novel analytical methodologies for metals, alloys, and high-purity materials using mass spectrometric and spectroscopic techniques. His expertise includes glow discharge quadrupole mass spectrometry and electrolyte cathode discharge atomic emission spectrometry, contributing to advancements in trace and ultra-trace analysis. His work has been widely recognized, leading to 32 publications in reputed international journals. Since 2023, he has been heading the ultra-trace analysis section at NCCCM, overseeing critical research in compositional characterization. He is also an active peer reviewer for international journals. With extensive experience in spectrometric techniques, Shekhar Raparthi plays a key role in material characterization for nuclear, industrial, and high-tech applications.

🏅Awards: 

Shekhar Raparthi has received several accolades for his significant contributions to analytical chemistry and mass spectrometry. His infrared spectroscopic method for oxygen quantification in TiCl₄ was widely appreciated in the titanium industry, earning him recognition in the field. His research on glow discharge quadrupole mass spectrometry and matrix volatilization methodologies for ultra-trace characterization of high-purity germanium has been published in top international journals, including Analytical Chemistry. His expertise in trace element analysis has made him a valuable asset to BARC and the Indian scientific community. As a distinguished member of ISMAS and ISAS, he actively contributes to the advancement of analytical sciences in India. While he has not listed specific awards, his impactful research, numerous peer-reviewed publications, and leadership in ultra-trace analysis solidify his reputation as a leading scientist in compositional characterization.

🔬Research Focus:

Shekhar Raparthi’s research revolves around trace and ultra-trace characterization of materials using advanced mass spectrometric and spectroscopic techniques. His work plays a crucial role in ensuring the purity and compositional accuracy of metals, alloys, and high-purity materials. He has pioneered glow discharge quadrupole mass spectrometry (GD-QMS) for detecting impurities at ultra-trace levels. Additionally, his development of matrix volatilization methodologies has enhanced the characterization of high-purity germanium, a material critical in semiconductor and radiation detection applications. His innovations in electrolyte cathode discharge atomic emission spectrometry (ECD-AES) have improved the sensitivity and precision of trace element analysis. His research significantly contributes to nuclear, industrial, and advanced material applications, ensuring high accuracy in material compositional studies. As the head of the ultra-trace analysis section at NCCCM, his expertise in **

Publication Top Notes:

In-situ Ti–Ir and ammonium thiocyanate modifiers for improvement of sensitivity of Sc to sub parts per billion levels and its accurate quantification in coal fly ash and red mud by GFAAS

Hydrophobicity induced graphene oxide based dispersive micro solid phase extraction of strontium from seawater and groundwater prior to GFAAS determination

Direct determination of ultra-trace sodium in reactor secondary coolant waters and other waters by electrolyte cathode discharge atomic emission spectrometry

Citation Count: 1

 

Assoc. Prof. Dr. Yue-Jin Liu | Organic Chemistry | Green Chemistry Award

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Assoc. Prof. Dr. Yue-Jin Liu | Organic Chemistry | Green Chemistry Award

Assoc. Prof. Dr. Yue-Jin Liu | Organic Chemistry | Hubei University ,China

Dr. Yue-Jin Liu is an Associate Professor at Hubei University, specializing in organic chemistry and catalytic transformations. His research primarily focuses on developing novel methodologies for inert chemical bond activation, particularly carbon-hydrogen (C–H) bond functionalization. Dr. Liu has made significant contributions to the field by designing innovative strategies for multi-component reactions, paving the way for more efficient synthesis of biologically active molecules and functional organic compounds. His recent work on ruthenium-catalyzed remote C–H functionalization of naphthalenes has been widely recognized. Dr. Liu has published in leading journals such as Chemical Science, contributing valuable insights to the scientific community. Despite his intensive academic engagements, he continues to explore new synthetic strategies that promote sustainable and green chemistry approaches. Dr. Liu’s dedication to advancing organic synthesis has established him as an emerging expert in the field, with an ever-growing impact on modern synthetic methodologies.

Professional Profile :         

Orcid

Scopus 

Summary of Suitability for Award:

Dr. Yue-Jin Liu’s research focuses on developing novel organic synthesis methods with an emphasis on C–H bond activation, a key aspect of green chemistry. His work on ruthenium-catalyzed three-component reactions enables efficient, modular, and atom-economical synthesis of multifunctional naphthalenes. This aligns with green chemistry principles by minimizing waste, reducing the need for hazardous reagents, and enhancing reaction efficiency. His catalyst-driven methodologies promote sustainable chemical transformations, making his research highly relevant to the Green Chemistry Award category. Dr. Yue-Jin Liu’s contributions to sustainable organic synthesis through C–H activation strategies make him a strong contender for the “Green Chemistry Award”. His work reduces environmental impact by utilizing direct functionalization approaches, avoiding toxic reagents, and increasing efficiency in organic synthesis. These advancements have significant implications for eco-friendly chemical manufacturing, supporting global sustainability goals.

🎓Education:

Dr. Yue-Jin Liu pursued his higher education in organic chemistry, focusing on advanced synthesis and catalysis. He obtained his Bachelor’s, Master’s, and Ph.D. degrees from prestigious institutions where he specialized in carbon-hydrogen bond activation and synthetic methodologies. His doctoral research laid the foundation for his career, emphasizing transition-metal-catalyzed organic transformations. During his academic journey, Dr. Liu worked under the guidance of renowned chemists, gaining expertise in molecular design, reaction mechanisms, and green synthetic approaches. Throughout his education, he engaged in multiple research projects that contributed to the development of new catalytic systems. His commitment to innovation and excellence in organic synthesis has led him to a successful career in academia, where he continues to mentor students and advance research in C–H activation. His strong academic background serves as the backbone of his contributions to the field of organic and medicinal chemistry.

🏢Work Experience:

Dr. Yue-Jin Liu currently serves as an Associate Professor at Hubei University, where he focuses on organic synthesis and catalysis. With years of experience in developing new methodologies for carbon-hydrogen bond activation, he has contributed significantly to green chemistry and efficient molecular synthesis. His expertise extends to transition-metal catalysis, multi-component reactions, and synthetic applications in biologically active molecules. Dr. Liu has led several research projects, including the ruthenium-catalyzed three-component tandem remote C–H functionalization of naphthalenes, which has enhanced the efficiency of modular synthesis. Beyond academia, he actively collaborates with researchers worldwide, contributing to high-impact publications in Chemical Science. His commitment to teaching and mentoring young researchers has shaped the next generation of scientists in organic chemistry. Dr. Liu’s extensive experience in synthetic methodologies continues to drive forward the boundaries of modern organic transformations.

🏅Awards: 

Dr. Yue-Jin Liu’s groundbreaking work in organic synthesis and catalysis has earned him recognition in the scientific community. His research on C–H activation strategies has been cited extensively, reflecting his contributions to green chemistry and innovative molecular synthesis. In 2025, he was nominated for the Green Synthesis Award for his pioneering work on ruthenium-catalyzed multi-component reactions. His publications in top-tier journals like Chemical Science have solidified his reputation as an emerging leader in organic chemistry. Despite his focus on fundamental research, Dr. Liu’s methodologies have practical applications in pharmaceutical synthesis and materials chemistry, earning him academic accolades. He continues to strive for excellence, pushing the boundaries of modern synthetic techniques and contributing to sustainable chemical transformations. His commitment to innovation and environmental responsibility has positioned him as a rising figure in green and sustainable chemistry.

🔬Research Focus:

Dr. Yue-Jin Liu’s research is dedicated to developing novel strategies for carbon-hydrogen (C–H) bond activation, aiming to create efficient, sustainable, and selective organic transformations. His work emphasizes multi-component reactions (MCRs), enabling the synthesis of complex molecular frameworks with high atom economy. A significant part of his research involves ruthenium-catalyzed tandem remote C–H functionalization, which facilitates the modular and concise synthesis of multifunctional naphthalenes. His studies contribute to green chemistry, reducing the need for harsh reagents and wasteful synthetic steps. Dr. Liu also explores transition-metal catalysis and ligand-controlled selectivity, expanding the scope of synthetic methodologies for biologically active compounds. His innovative approaches have potential applications in drug discovery, materials science, and fine chemical production. By integrating computational chemistry and experimental design, he continuously seeks to enhance reaction efficiency, selectivity, and sustainability in modern organic synthesis.

Publication Top Notes:

Cobalt(II)-Catalyzed Selective C2–H Heck Reaction of Native (N–H) Indoles Enabled by Salicylaldehyde Ligand

Salicylaldehyde-Enabled Co(II)-Catalyzed Oxidative C–H Alkenylation of Indoles with Olefins

Ruthenium-Catalyzed Three-Component Tandem Remote C–H Functionalization of Naphthalenes: Modular and Concise Synthesis of Multifunctional Naphthalenes

Mild C−H Alkoxylation of Aromatic Amides Catalyzed by Salicylaldehyde‐Co(II) Complexes

Cobalt/Salicylaldehyde-Enabled C–H Alkoxylation of Benzamides with Secondary Alcohols under Solvothermal Conditions

Salicylaldehyde-Cobalt(II)-Catalyzed C–H Alkoxylation of Indoles with Secondary Alcohols

Selective Synthesis of Sulfonamides and Sulfenamides from Sodium Sulfinates and Amines

Rapid Modular Synthesis of Indole Ethers via Dehydrogenative Cross-Coupling Reaction of Indoles and Alcohols

Remote C5-Selective Functionalization of Naphthalene Enabled by P–Ru–C Bond-Directed δ-Activation

Ru(II)-Catalyzed P(III)-Assisted C8-Alkylation of Naphthphosphines

Ruthenium-Catalyzed Meta-Difluoromethylation of Arene Phosphines Enabled by 1,3-Dione

Salicylaldehyde-Promoted Cobalt-Catalyzed C–H/N–H Annulation of Indolyl Amides with Alkynes: Direct Synthesis of a 5-HT3 Receptor Antagonist Analogue