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

Published on 01/07/202501/07/2025 by Chemistry Awards

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

Assist. Prof. Dr. Jonghyun Eun | Polymer Chemistry | Best Researcher Award

Published on 26/05/202526/05/2025 by Chemistry Awards

Assist. Prof. Dr. Jonghyun Eun | Polymer Chemistry | Best Researcher Award

Assist. Prof. Dr. Jonghyun Eun , Polymer Chemistry , Professor at Kumoh National Institute of Technology, South Korea

Dr. Jong-Hyun Eun is an Assistant Professor in the Department of Materials Design Engineering at Kumoh National Institute of Technology, Republic of Korea. With a strong background in textile engineering and advanced fiber materials, he specializes in carbon fiber technologies, piezoelectric nanofibers, and composite materials. He earned his integrated Master’s and Ph.D. from Yeungnam University under the mentorship of Prof. Joon-Seok Lee. His postdoctoral research journey included positions at Arizona State University and Yeungnam University, where he advanced his expertise in carbon fiber reinforced plastics (CFRPs), graphene-metal composites, and electrospun nanofibers. Dr. Eun has hands-on experience in fabricating and analyzing high-performance composites and energy harvesting materials, making him a rising researcher in the field. He also contributes actively to teaching, mentoring students in textile and fashion materials design. His recent publications highlight innovations in hydrogen storage, nanofiber processing, and sustainable composite development.

Professional Profile :

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Summary of Suitability for Award:

Dr. Jong-Hyun Eun demonstrates a strong and dynamic research profile with focused expertise in carbon fiber technology, composite materials, piezoelectric nanofibers, and textile engineering—areas that are highly relevant to both academic advancement and industrial applications. His research is deeply interdisciplinary, integrating materials science, nanotechnology, and energy harvesting, aligning well with global trends in sustainable and smart materials. Dr. Jong-Hyun Eun is highly suitable for nomination for the “Best Researcher Award”. He brings together innovative research, technical excellence, and cross-disciplinary impact. His rapid trajectory from graduate studies to international postdoctoral work and faculty appointment, combined with a productive publication record and active teaching, makes him a strong contender. His ongoing contributions in composite materials and energy harvesting nanofibers address current scientific and technological challenges, fulfilling the criteria for excellence in research.

🎓Education:

Dr. Jong-Hyun Eun holds an integrated Master’s and Doctoral degree in Textile Engineering and Technology from Yeungnam University (2015–2021), where he conducted research under Prof. Joon-Seok Lee. His doctoral work focused on the development of polyethylene-based carbon fibers and composite materials. Prior to that, he completed a B.S. in Fiber and New Materials Design Engineering (2009–2015) at the same university, also under Prof. Lee’s guidance. Throughout his academic journey, Dr. Eun built a solid foundation in textile science, polymer engineering, and nanotechnology. His studies covered a range of topics from sulfonation processes under hydrostatic pressure to advanced electrospinning systems. His rigorous academic training has equipped him with both theoretical knowledge and extensive laboratory experience, paving the way for impactful research in fiber engineering and sustainable composite technologies.

🏢Work Experience:

Dr. Jong-Hyun Eun’s professional experience spans academia and cutting-edge research in fiber science and materials engineering. He currently serves as an Assistant Professor at Kumoh National Institute of Technology. Previously, he was a Postdoctoral Researcher at Arizona State University (2021–2023), focusing on material design and composite innovation. Before that, he held a postdoctoral position at Yeungnam University (2021), continuing his work in textile engineering. During his graduate studies, he also taught various courses at Korea Polytechnic, such as high-tech fiber, woven fabric formation, and textile material analysis. His hands-on experience includes fabricating carbon fiber composites through various molding techniques, developing piezoelectric nanofibers via electrospinning, and analyzing graphene-metal composites. Dr. Eun’s diverse research roles and teaching responsibilities have allowed him to bridge material science with real-world applications.

🏅Awards:

While specific awards are not listed in the profile provided, Dr. Jong-Hyun Eun’s academic and professional achievements reflect a career of high distinction. Earning competitive postdoctoral positions at prestigious institutions like Arizona State University and Yeungnam University speaks to his expertise and scholarly recognition. His continuous collaboration with renowned Professor Joon-Seok Lee and multiple first-author publications in high-impact journals such as Scientific Reports, Materials & Design, and International Journal of Hydrogen Energy highlight his contributions to materials science and textile engineering. His role as a lead contributor in cutting-edge research on carbon fibers and composite materials demonstrates his leadership and innovation. As his career progresses, he is poised to receive further accolades in recognition of his impactful research and teaching in advanced materials engineering.

🔬Research Focus:

Dr. Jong-Hyun Eun’s research is centered on advanced fiber and composite materials, with a strong focus on sustainability and performance. His expertise includes carbon fiber development from polyethylene, toughening mechanisms in carbon fiber reinforced plastics (CFRPs), and mechanical/impact resistance analysis. He is also deeply engaged in developing piezoelectric nanofiber energy harvesting devices using electrospinning techniques, aiming at efficient wearable energy solutions. Additionally, his research extends to graphene-metal composites, exploring their structural and thermal properties. Through multidisciplinary approaches, Dr. Eun investigates reaction mechanisms, interfacial behavior, and processing-structure-property relationships in fiber-reinforced materials. His work is driven by a commitment to innovation in energy materials, lightweight composites, and next-generation textile engineering, making significant contributions to both academia and industry.

Publication Top Notes:

Effect of MWCNT content on the mechanical and piezoelectric properties of PVDF nanofibers
Citations: 83

Effect of low melting temperature polyamide fiber-interlaced carbon fiber braid fabric on the mechanical performance and fracture toughness of CFRP laminates
Citations: 32

Evaluation of carbon fiber and p-aramid composite for industrial helmet using simple cross-ply for protecting human heads
Authors: S. Kim, J. Lee, C. Roh, J. Eun, C. Kang
Citations: 32

Study on polyethylene-based carbon fibers obtained by sulfonation under hydrostatic pressure
Citations: 14

Effect of the viscosity of polyvinyl chloride resin and weaving structures of polyester fabric on the off-axis mechanical properties of PVC coated fabric
Citations: 9

Study on the NCO index and base knitted fabric substrates on the thermal, chemical, and mechanical properties of solvent-less formulations polyurethane artificial leather
Citations: 8

A study on mechanical properties and thermal properties of UHMWPE/MWCNT composite fiber with MWCNT content and draw ratio
Citations: 7

Effect of fabricating temperature on the mechanical properties of spread carbon fiber fabric composites
Citations: 7

Effect of toughened polyamide-coated carbon fiber fabric on the mechanical performance and fracture toughness of CFRP
Citations: 6

Effect of toughened polyamide/carbon fiber interlace braid fabric on the mechanical performance of CFRP laminates
Citations: 2

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

Published on 09/05/202509/05/2025 by Chemistry Awards

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 :

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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

Prof. Reine NEHME | Analytical Chemistry | Best Researcher Award

Published on 05/05/202505/05/2025 by Chemistry Awards

Prof. Reine NEHME | Analytical Chemistry | Best Researcher Award

Prof. Reine NEHME, Analytical Chemistry , Head of analytical team at University of Orléans, ICOA UMR7311, France

Prof. Reine Nehmé is a renowned French scientist and Professor of Analytical Sciences at the University of Orléans, where she leads the “Analytical Strategies, Affinities and Bioactives” team at ICOA. With over 15 years of academic and research experience, she specializes in advanced separation techniques, bioanalysis, and microfluidics. She is deeply involved in both teaching and scientific governance—serving on multiple university and national scientific committees. Prof. Nehmé also contributes to scientific advancement as a supervisor of numerous Ph.D. and post-doctoral researchers and by coordinating key national research projects funded by ANR and regional bodies. Her prolific contributions to analytical chemistry are reflected in her numerous publications, particularly in the areas of enzymatic assays, capillary electrophoresis, and bioactive compound analysis. With a strong leadership role in Afsep and her involvement in high-level academic administration, she is recognized as a leading figure in analytical chemistry in France and Europe.

Professional Profile :

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Summary of Suitability for Award:

Prof. Nehmé holds a Ph.D. in Analytical Chemistry from the University of Montpellier (2008) and an HDR (Accreditation toSupervise Research) from the University of Orléans (2016). Her academic background demonstrates deep expertise and a commitment to high-level scientific scholarship. As a professor and group leader at ICOA, University of Orléans, she leads the “Analytical Strategies, Affinities and Bioactives” team, driving impactful research in analytical sciences, especially in bioanalysis, separative techniques, capillary electrophoresis, microfluidics, and mass spectrometry. Prof. Nehmé is deputy treasurer and a management committee member of the Capillary Electrophoresis Group of Afsep. She holds leadership roles at her university and is actively engaged in curriculum design, evaluation panels, and scientific committees. Prof. Reine Nehmé exemplifies the ideal profile for a “Best Researcher Award”: a high-impact scientist, strategic research leader, dedicated educator, and committed scientific community member. Her strong publication record, funded projects, mentoring, and institutional service collectively highlight her as a trailblazer in analytical chemistry. She fully deserves recognition through such a prestigious award.

🎓Education:

Prof. Reine Nehmé earned her Ph.D. in Analytical Chemistry from the University of Montpellier in 2008, following her Master’s degree (Master 2) in the same field from the same institution in 2005. Demonstrating her continued academic excellence and expertise, she received her Habilitation to Supervise Research (HDR) from the University of Orléans in 2016. This qualification represents the highest academic degree in France and reflects her capacity to independently lead doctoral research and large-scale scientific projects. Her academic training laid a robust foundation in analytical methodologies, chromatographic techniques, and advanced spectroscopy. These qualifications have enabled her to contribute extensively to the development of innovative analytical tools and methods in environmental, biological, and pharmaceutical research. Her educational background not only established her scientific depth but also positioned her to take on leadership and mentoring roles across both academic and research platforms.

🏢Work Experience:

Prof. Nehmé began her academic journey at the University of Orléans in 2008 as a Temporary Teaching and Research Assistant (ATER). She advanced to Associate Professor in 2009 and was promoted to Professor in 2019. Over the years, she has held multiple leadership roles, including Head of the Analytical Chemistry Department and Coordinator of the Professional License program in Chemistry at IUT Chimie d’Orléans. She has been a member of the laboratory’s scientific council since 2017, and also serves on the Commission of Disciplinary Experts. As an active educator, she teaches a range of courses in analytical sciences including electrochemistry, chromatography, mass spectrometry, and microfluidics. In research, she has successfully supervised 6 Ph.D. students (2 ongoing) and multiple post-doctoral and master’s interns. Her contributions extend to national committees such as Afsep’s CE group, where she has served as Deputy Treasurer since 2021.

🏅Awards:

While specific awards are not explicitly listed, Prof. Reine Nehmé’s honors are evidenced by her numerous leadership and elected roles. She received the Habilitation to Supervise Research (HDR), a distinguished recognition in France for scholarly excellence. Her long-standing position on the scientific council of the ICOA laboratory and as a Commission Expert in disciplinary affairs at the University of Orléans speaks to her academic credibility. She was elected to the Management Committee of the CE group of Afsep in 2017 and appointed as Deputy Treasurer in 2021, underlining national recognition by her peers. She has consistently been entrusted with leadership in nationally funded research programs by ANR and regional agencies, confirming her scientific standing and project leadership ability. Her active role in supervising doctoral candidates and international collaborations further affirms her status as a respected figure in analytical sciences.

🔬Research Focus:

Prof. Nehmé’s research centers on analytical sciences, particularly in capillary electrophoresis, mass spectrometry, and microscale thermophoresis for studying molecular interactions. Her projects frequently explore bioanalysis, enzyme kinetics, and natural product evaluation. She leads or participates in numerous ANR-funded projects, including stapled peptide design, bioremediation via micromycetes, and enzyme behavior in crowded synthetic environments. A significant part of her work involves developing lab-on-a-chip (LoC) platforms for investigating target-ligand interactions at the single-cell level. She has also contributed to the miniaturization of enzymatic assays, passive sampling techniques for water analysis, and electrochemical sensors for environmental monitoring. Prof. Nehmé integrates separation sciences with biology and materials chemistry, bridging analytical method development with real-world biological and environmental challenges. Her interdisciplinary research fosters innovations in diagnostics, therapeutic monitoring, and ecological risk assessment, marking her as a pioneer in translating analytical chemistry into functional tools for bioactive discovery and environmental stewardship.

Publication Top Notes:

1. Using CE to Confirm the Activity of Fluorescent miRFP670-LIMK1 Protein Produced for MST Assays Directly in Cell Lysate

2. The Antimicrobial Activity of ETD151 Defensin is Dictated by the Presence of Glycosphingolipids in the Targeted Organisms

3. Glycolipid and Lipopeptide Biosurfactants: Structural Classes and Characterization—Rhamnolipids as a Model

4. Nutraceutical and Cosmetic Applications of Bioactive Compounds of Saffron (Crocus Sativus L.) Stigmas and Its By-products

5. Antioxidant and Anti-lipase Capacities from the Extracts Obtained from Two Invasive Plants: Ambrosia artemisiifolia and Solidago canadensis

6. Nutraceutical Capacities of Extracts from the Invasive Plants Ambrosia artemisiifolia and Solidago canadensis

7. Screening and Evaluation of Dermo-Cosmetic Activities of the Invasive Plant Species Polygonum cuspidatum

8. Biosurfactant-Producing Mucor Strains: Selection, Screening, and Chemical Characterization

9. Capillary Electrophoresis for Enzyme-Based Studies: Applications to Lipases and Kinases

10. Correction to: Reproducibility and Accuracy of Microscale Thermophoresis in the NanoTemper Monolith: A Multi Laboratory Benchmark Study

11. Design, Synthesis and SAR in 2,4,7-Trisubstituted Pyrido[3,2-d]Pyrimidine Series as Novel PI3K/mTOR Inhibitors

Assist. Prof. Dr. Changtong YANG | Medicinal Chemistry | Best Researcher Award

Published on 05/05/202505/05/2025 by Chemistry Awards

Assist. Prof. Dr. Changtong YANG | Medicinal Chemistry | Best Researcher Award

Assist. Prof. Dr. Changtong YANG , Medicinal Chemistry, Radiochemist/Chemist at Singapore General Hospital, Singapore

Dr. Chang-Tong Yang is a renowned radiochemist based in Singapore, specializing in radiopharmaceuticals and molecular imaging. He currently serves as an Assistant Professor in the Radiological Science Academic Clinical Programme at Duke-NUS Medical School and as a Radiochemist at Singapore General Hospital. With over two decades of experience, Dr. Yang has made significant contributions to the development of nuclear imaging probes and radiolabeled therapeutics. His research career spans prestigious institutions, including Nanyang Technological University and A*STAR. Dr. Yang is internationally recognized for advancing nanomaterial probes and novel radiolabeling strategies. He has authored impactful publications in top-tier journals, reflecting his innovation in theranostics, radiochemistry, and nanomedicine. With a strong background in academic and clinical research, Dr. Yang continues to shape the future of molecular imaging for personalized medicine. His global education and interdisciplinary expertise make him a leading figure in translational radiochemistry research.

Professional Profile :

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Summary of Suitability for Award:

Dr. Chang-Tong Yang exemplifies the qualities of a “Best Researcher Award” recipient. His innovative contributions to radiochemistry and molecular imaging, combined with a strong publication record, interdisciplinary leadership, and global training, establish him as a trailblazer in translational medical research. His work is not only scientifically rigorous but also clinically impactful, directly advancing the field of nuclear medicine. Therefore, he is highly recommended for recognition as a top-tier researcher deserving of this award.

🎓Education:

Dr. Chang-Tong Yang received his Ph.D. in Chemistry from the National University of Singapore (1998–2002), where he laid the foundation for his career in radiochemistry. He further enhanced his expertise with postdoctoral fellowships at three prestigious U.S. institutions: University of Iowa (2003–2005), University of Michigan (2005–2006), and Purdue University (2006–2007), focusing on chemistry and health sciences. These formative years provided Dr. Yang with a multidisciplinary perspective in synthetic chemistry, radiopharmaceutical development, and imaging sciences. His international training exposed him to cutting-edge methodologies and collaborative projects across biomedical research, which he has since translated into innovative imaging solutions. The combination of rigorous education and hands-on research across these top institutions shaped his ability to bridge fundamental science with clinical applications, particularly in nuclear medicine and molecular imaging.

🏢Work Experience:

Dr. Chang-Tong Yang brings extensive professional experience across both academic and clinical research settings. He is currently an Assistant Professor at Duke-NUS Medical School (2020–present) under the Radiological Science ACP, focusing on radiopharmaceutical sciences. Concurrently, he serves as a Radiochemist at Singapore General Hospital (2018–present) in the Department of Nuclear Medicine & Molecular Imaging, where he translates research into clinical practice. Prior to that, he worked as a Senior Scientist at Nanyang Technological University (2014–2018), contributing to molecular imaging initiatives within the Lee Kong Chian School of Medicine. He also held a Senior Scientist role at A*STAR’s Singapore Bio-Imaging Consortium (2007–2014), leading various radiochemistry research programs. Across these roles, Dr. Yang has developed and validated imaging agents, optimized radiolabeling techniques, and led translational studies that impact diagnostic imaging and therapeutic strategies. His multidisciplinary engagements underscore his pivotal role in bridging chemistry and medicine.

🏅Awards:

While specific awards are not listed in the available data, Dr. Chang-Tong Yang’s extensive contributions to radiopharmaceuticals and molecular imaging reflect a highly respected and impactful career. His appointments at top institutions such as Duke-NUS, A*STAR, and Singapore General Hospital indicate peer recognition and institutional trust. His publications in reputed journals such as Molecules, Nanomaterials, and Drug Discovery Today highlight his standing in the scientific community. His ongoing leadership roles and collaboration with clinicians further underscore professional acknowledgment of his expertise. Dr. Yang’s selection for multiple postdoctoral positions at prestigious U.S. institutions—University of Iowa, University of Michigan, and Purdue University—suggests early recognition of his academic promise. His interdisciplinary contributions to nuclear medicine, nanotechnology, and molecular imaging may have earned him internal institutional awards, research grants, and invitations to present at scientific forums, which commonly accompany such roles.

🔬Research Focus:

Dr. Chang-Tong Yang’s research is centered on radiopharmaceutical science, with a strong emphasis on the development of molecular imaging probes and radiolabeled nanomaterials for diagnostic and therapeutic applications. His expertise lies in designing novel radioisotope-labeled compounds for use in nuclear medicine imaging techniques such as PET and SPECT, targeting cancer and other pathological conditions. He is particularly interested in enhancing the in vivo behavior of nanomaterial-based agents, improving tumor targeting, retention, and safety. Dr. Yang also explores the biocompatibility and stability of these probes, including how formulation and labeling protocols influence their function. His translational work bridges laboratory innovations with clinical imaging requirements, enabling personalized diagnostics and theranostic approaches. Furthermore, he investigates radiochemical compatibility in clinical settings, such as the mixing of imaging agents with contrast media, which supports safe and effective imaging protocols. His work integrates chemistry, imaging, and clinical practice seamlessly.

Publication Top Notes:

1. pH-Induced In Situ Aggregation of Cu₂₋ₓSe-POED with Extended Tumor Retention for Enhanced Chemodynamic/Photothermal Therapy

2. Standard Radio-Iodine Labeling Protocols Impaired the Functional Integrity of Mesenchymal Stem/Stromal Cell Exosomes

3. Radiolabeled Liposomes for Nuclear Imaging Probes

4. Radiochemical Feasibility of Mixing of 99mTc-MAA and 90Y-Microspheres with Omnipaque Contrast

5. Nanomaterial Probes for Nuclear Imaging

6. Positron Emission Tomographic Imaging in Drug Discovery

7. An In Vivo Study of a Rat Fluid-Percussion-Induced Traumatic Brain Injury Model with [11C]PBR28 and [18F]flumazenil PET Imaging

8. Gadolinium-Based Bimodal Probes to Enhance T1-Weighted Magnetic Resonance/Optical Imaging

9. Activatable Cell-Penetrating Peptide Conjugated Polymeric Nanoparticles with Gd-Chelation and Aggregation-Induced Emission for Bimodal MR and Fluorescence Imaging of Tumors

10. Dealing with PET Radiometabolites

11. PET-MR and SPECT-MR Multimodality Probes

Mr. Frédéric Pignon | Chemical Engineering | Best Researcher Award

Published on 30/04/202530/04/2025 by Chemistry Awards

Mr. Frédéric Pignon | Chemical Engineering | Best Researcher Award

Mr. Frédéric Pignon , Chemical Engineering ,Senior Scientist at CNRS/Laboratoire Rhéologie et Procédés, France

Frédéric Pignon is a Senior Scientist (Directeur de Recherche, DR1) at CNRS, affiliated with the Laboratoire Rhéologie et Procédés (LRP), UMR 5520, Grenoble, France.🇫🇷, he specializes in fluid mechanics and soft matter rheology. With over 25 years of expertise, Pignon has significantly contributed to the understanding of the multiscale structural behavior of anisotropic dispersions under various flow conditions. His pioneering development of in situ experimental setups has enabled novel insights into flow-structure relationships using SAXS, SANS, SALS, and ultrasound techniques. He holds an h-index of 32 📊, with 76 international publications, 2 patents, and numerous invited talks globally . Apart from research, he actively contributes to scientific evaluation committees and review panels including ANR, HCERES, and ESRF. His collaborations span leading institutions in Europe, North America, and Asia, positioning him as a key figure in advanced rheological material research.

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Summary of Suitability for Award:

Dr. Pignon holds a Ph.D. in Fluid Mechanics and Transfer (1997, Grenoble-INP), with prior DEA in the same field. His formal training is strongly aligned with his long-term research focus in rheology and multiscale fluid dynamics. He has published 76 peer-reviewed international journal papers, presented in 97 international conferences (including 8 invited talks), and holds 2 patents. His h-index of 32 demonstrates sustained impact in his field. His research uniquely combines rheometric properties with nanoscale-to-microscale structural characterization using advanced techniques such as SAXS, SALS, and optical methods. These contributions have significantly advanced the understanding of flow-induced behavior in complex fluids and materials. Dr. Frédéric Pignon’s pioneering research, prolific publication record, significant mentoring, leadership in scientific boards, and innovative patent contributions make him exceptionally well-qualified for the “Best Researcher Award”. His work bridges theoretical insight with experimental innovation in fluid mechanics and nanostructured systems, making a deep impact on science and industry alike. He is a model of scientific excellence and leadership.

🎓Education:

Frédéric Pignon pursued higher education in engineering and fluid mechanics in France. In 1993, he earned his D.E.A. (Diplôme d’Études Approfondies) in Fluid Mechanics and Transfer from Grenoble-INP, one of France’s premier engineering institutions 🎓. He deepened his specialization by completing a Ph.D. in Fluid Mechanics and Transfer at the same institution in January 1997, underlining his early interest in the microstructural behavior of complex fluids. His doctoral research laid the foundation for his later pioneering work in multiscale flow characterization. Pignon’s strong academic formation in physics, transport phenomena, and complex systems gave him a robust foundation to innovate in rheometry and structural analysis of soft matter systems. His academic path reflects a consistent focus on multidisciplinary approaches to fluid behavior, bridging physics, materials science, and applied engineering.

🏢Work Experience:

Frédéric Pignon has held leading research positions within the CNRS system for over two decades 🧪. Since October 2013, he serves as Senior Scientist (DR1) at CNRS-LRP, following a 14-year tenure (1999–2013) as Research Scientist (CR1). Earlier, he conducted postdoctoral research at ESRF’s ID28 Beamline (1999) and Laboratoire Rhéologie et Procédés (LRP) (1997–1998) 🔬. His research career is defined by designing cutting-edge experimental cells that integrate rheology with structural probes (SAXS/SANS/optical methods). He supervises Ph.D. students and postdoctoral researchers, participates actively in international collaborations, and leads major research projects across France and Europe. Pignon’s extensive academic and industrial network has facilitated groundbreaking studies on anisotropic particles, biopolymers, and colloids under dynamic conditions. He also contributes to scientific governance through involvement in evaluation panels (ESRF, ANR, HCERES), steering strategic research and innovation.

🏅Awards:

Frédéric Pignon’s research excellence has been recognized through leadership roles, panel appointments, and competitive research funding . He is a long-standing member of the ESRF Review Committee (Panel C08) (2014–present) and served on France’s ANR CES 09 panel (2018). He also contributed to institutional evaluation through HCERES Committee vague C (2016–2017). As Co-PI of Labex Tec 21 (2013–2021) and scientific coordinator for Carnot PolyNat Institute projects, he has driven interdisciplinary research strategies. Pignon holds two patents, including one on thixotropic hydrogels and another on an ultrasound-enhanced filtration device 🔬. He has secured significant funding from national and regional sources (ANR, SATT, Région Bretagne), supervising several Ph.D. and postdoctoral projects. His work is frequently cited and referenced in the scientific community, and he is a regular reviewer for top-tier journals and national research proposals, having completed 83 international journal reviews and 7 ANR project reviews.

🔬Research Focus:

Frédéric Pignon’s research bridges rheology, soft matter physics, and multiscale characterization. His expertise lies in understanding how anisotropic particles—like cellulose nanocrystals and clay platelets—organize under flow, pressure, or acoustic fields. By developing custom in situ setups integrating rheometers with SAXS, SANS, birefringence, and SALS, he studies how microstructure impacts mechanical properties during dynamic processing. His group investigates orientation, aggregation, concentration polarization, and gelation in suspensions, particularly during cross-flow filtration and ultrasound exposure. He also explores bio-based nanomaterials and the physical behavior of hydrogels, enabling applications in biotechnology and green materials. Collaborating with synchrotron and neutron facilities, he probes structures from nanometer to micrometer scales. Projects like ANR ANISOFILM and Memus (SATT Linksium) showcase his role in advancing filtration, structural control, and nanocomposite design. His research is highly interdisciplinary, combining physics, chemistry, and process engineering.

Publication Top Notes:

1. Multi-scale investigation of the effect of photocurable polyethylene glycol diacrylate (PEGDA) on the self-assembly of cellulose nanocrystals (CNCs)

2. A self-cleaning biocatalytic membrane with adjusted polyphenol deposition for edible oil-water separation

3. A scalable and eco-friendly carbohydrate-based oleogelator for vitamin E controlled delivery

4. Orthotropic organization of a cellulose nanocrystal suspension realized via the combined action of frontal ultrafiltration and ultrasound as revealed by in situ SAXS

5. Viologen-based supramolecular crystal gels: gelation kinetics and sensitivity to temperature

6. Molecular mechanism of casein-chitosan fouling during microfiltration

7. Multiscale investigation of viscoelastic properties of aqueous solutions of sodium alginate and evaluation of their biocompatibility

8. Self-supported MOF/cellulose-nanocrystals materials designed from ultrafiltration

9. Orientation of Cellulose Nanocrystals Controlled in Perpendicular Directions by Combined Shear Flow and Ultrasound Waves Studied by Small-Angle X-ray Scattering

10. Effect of Polymer Length on the Adsorption onto Aluminogermanate Imogolite Nanotubes

Citations: 3

11. Breakdown and buildup mechanisms of cellulose nanocrystal suspensions under shear and upon relaxation probed by SAXS and SALS

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

Published on 09/04/202509/04/2025 by Chemistry Awards

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 :

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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”

Dr. SHEKHAR RAPARTHI | Analytical Chemistry | Best Researcher Award

Published on 06/03/2025 by Chemistry Awards

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.

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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

Prof. Dr. Pengwei Zhao | Medicinal Chemistry | Best Researcher Award

Published on 22/02/202522/02/2025 by Chemistry Awards

Prof. Dr. Pengwei Zhao | Medicinal Chemistry | Best Researcher Award

Prof. Dr. Pengwei Zhao | Medicinal Chemistry | Ph.D., Master’s Supervisor at Inner Mongolia Medical University, School of Basic Medical Sciences, China

Dr. Pengwei Zhao is a Professor at the School of Basic Medical Sciences, Inner Mongolia Medical University, he serves as a master’s supervisor and holds various academic positions. He is a member of the Jiusan Society and actively contributes to scientific research as a registered reviewer for Medical Science Monitor and Chinese Journal of Tissue Engineering Research. He is also a youth editorial board member of Modern Oncology and a director of the Inner Mongolia Bioengineering Society. His research focuses on tumor immunology and pharmacological mechanisms of Mongolian medicine. Dr. Zhao has led multiple national and regional research projects, including studies on β-defensins, immune resistance, and cancer treatment mechanisms. His contributions to microbiology and oncology are widely recognized, with several impactful publications in international journals.

Professional Profile :

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Summary of Suitability for Award:

Dr. Pengwei Zhao, a distinguished Professor at Inner Mongolia Medical University, has made significant contributions to tumor immunology, cancer pharmacology, and Mongolian medicine. His research on β-defensins and their role in immune modulation and cancer therapy has led to groundbreaking findings, particularly in colorectal and triple-negative breast cancer (TNBC). With numerous high-impact publications, including in Pharmacogenomics Journal and World Journal of Gastrointestinal Oncology, his work is recognized globally. His ongoing National Natural Science Foundation of China project further highlights his leadership in cancer research. Dr. Pengwei Zhao’s extensive research, innovative methodologies, and interdisciplinary approach make him an outstanding candidate for the “Best Researcher Award”. His contributions to immunotherapy, autophagy, and microbiome-related cancer treatments have the potential to shape future oncological therapies. Recognizing him with this award would honor his pioneering discoveries and impact on global cancer research.

🎓Education:

Dr. Pengwei Zhao holds a Ph.D. in Basic Medical Sciences with a specialization in tumor immunology and pharmacology. His doctoral research focused on β-defensin-mediated immune modulation and cancer therapy. He pursued his higher education at Inner Mongolia Medical University, where he developed expertise in molecular biology, pharmacology, and immunology. His early education emphasized microbiology and traditional Mongolian medicine. Dr. Zhao further enhanced his skills through postdoctoral research and collaborations with leading scientists in cancer biology. His education provided a strong foundation in oncological pharmacology, signaling pathways, and immune resistance mechanisms. He has continuously expanded his knowledge through national and international conferences, workshops, and training programs. His academic journey reflects a commitment to translational research, bridging basic science with clinical applications in cancer therapy.

🏢Work Experience:

Dr. Zhao has been a Professor at Inner Mongolia Medical University for several years, where he also serves as a Master’s Supervisor. His professional roles extend beyond teaching, as he holds multiple directorial positions in national and regional scientific societies. He is a reviewer for prestigious journals, including Medical Science Monitor and Chinese Journal of Digestive Diseases. As a youth editorial board member of Modern Oncology, he actively contributes to cancer research. He has successfully led multiple research projects funded by national and regional agencies, focusing on cancer immunology, microbiology, and Mongolian medicine-based therapies. Additionally, Dr. Zhao has conducted collaborative research on β-defensins, autophagy, and immune resistance mechanisms. His expertise in pharmacological pathways and microbial interactions has significantly advanced the understanding of cancer treatment. He has also been invited as a speaker and panelist at various oncology and pharmacology conferences.

🏅Awards:

Dr. Pengwei Zhao has received multiple prestigious awards and honors in recognition of his contributions to tumor immunology and Mongolian medicine research. He has been honored by the Inner Mongolia Medical University for excellence in research and mentorship. His work on β-defensins and their role in cancer has earned him accolades from Inner Mongolia’s Science and Technology Department. He has also received distinguished reviewer awards from journals such as Medical Science Monitor and Chinese Journal of Tissue Engineering Research. As a key member of the Chinese Society of Ethnomedicine and Pharmacy, he has been acknowledged for his research on the pharmacological mechanisms of traditional Mongolian medicine. His contributions to microbiology and immunology have been recognized by the Inner Mongolia Microbiology Society, and he has been invited as a young committee member of the Chinese Microbiological Society’s Clinical Microbiology Professional Committee.

🔬Research Focus:

Dr. Pengwei Zhao’s research primarily focuses on tumor immunology, cancer pharmacology, and the therapeutic potential of Mongolian medicine. He investigates the molecular mechanisms of β-defensins in cancer, particularly their role in immune regulation and tumor suppression. His work explores how β-defensin-1 peptides modulate PD-1/PD-L1 immune resistance in colorectal cancer. Additionally, he studies Mongolian medicinal formulations like Sendeng-4 and their mechanisms against skin cancer. His research also extends to microbiology, analyzing how bacterial infections, such as those caused by Staphylococcus aureus and Klebsiella pneumoniae, influence lung epithelial immune responses. Dr. Zhao has also contributed significantly to understanding long noncoding RNAs (lncRNAs) and their regulatory impact on autophagy pathways in cancer. His interdisciplinary approach integrates immunology, molecular biology, and ethnopharmacology, providing novel insights into cancer therapy, host-pathogen interactions, and the development of targeted immunotherapies.

Publication Top Notes:

Upregulation of p300 in paclitaxel-resistant TNBC: implications for cell proliferation via the PCK1/AMPK axis

Authors: P. Zhao, Pengwei; J. Cui, Jiaxian; X. Wang, Xiumei

Journal: Pharmacogenomics Journal

Year: 2024

Citations: 2

Human β-defensin-1 affects the mammalian target of rapamycin pathway and autophagy in colon cancer cells through long non-coding RNA TCONS_00014506

Authors: Y. Zhao, Yuxin; Y. Cui, Yan; X. Li, Xinhong; L. Bao, Lili; P. Zhao, Pengwei

Journal: World Journal of Gastrointestinal Oncology

Year: 2024

Citations: 3

Effect of Staphylococcus aureus in pneumonia mouse model on promotion of mBD-3 expression through ERK1/2

Authors: Yongqing Ni, Xiaoduo Bi, Pengwei Zhao

Ligilactobacillus salivarius LZZAY01 accelerated autophagy and apoptosis in colon cancer cells and improved gut microbiota in CAC mice

Authors: Yang W, Li T, An S, Chen R, Zhao Y, Cui J, Zhang M, Lu J, Tian Y, Bao L, Zhao P

Journal: Microbiol Spectrum

Year: 2025

LPS Promoted HPMEC Autophagy by Suppression of the PI3K/Akt/mTOR through Inhibited TIMAP-Promoted Moesin Expression in Sepsis

Authors: Jili Wen, Pengwei Zhao, HuiJuan Ren, JunMin Wu

Journal: Journal of Biological Regulators and Homeostatic Agents

Year: 2023

Dr. Jean Moto Ongagna | Theoretical Chemistry | Catalysis Award

Published on 17/02/202517/02/2025 by Chemistry Awards

Dr. Jean Moto Ongagna | Theoretical Chemistry | Catalysis Award

Dr. Jean Moto Ongagna | Theoretical Chemistry | Lecturer – University of Douala-Cameroon , Cameroon

Dr. Jean Moto Ongagna is a Cameroonian researcher specializing in Theoretical chemistry and Computational Chemistry . He obtained his Ph.D. from the University of Douala in 2021. His expertise spans Density Functional Theory (DFT), Pharmacokinetics (ADMET), Molecular Docking, Molecular Dynamics (MD), and ab initio Molecular Dynamics (ADMP). Dr. Ongagna has contributed significantly to computational chemistry, particularly in studying metal complexes, chemical bonding, and reaction mechanisms. He has participated in prestigious international conferences and workshops, presenting groundbreaking research on chemical bonding interactions. With numerous publications in high-impact journals such as RSC Advances and the International Journal of Quantum Chemistry, his work advances the understanding of transition metal complexes and their applications. He actively collaborates with researchers worldwide and is dedicated to developing computational tools for chemical and biological systems.

Professional Profile :

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Summary of Suitability for Award:

Dr. Jean Moto Ongagna is an outstanding candidate for the “Catalysis Awards”, given his significant contributions to computational catalysis and theoretical chemistry. His research extensively applies Density Functional Theory (DFT), Quantum Chemical Calculations, and Molecular Dynamics (MD) to investigate transition metal complexes, non-standard chemical bonding, and catalytic reaction mechanisms. His studies provide deep insights into metal-ligand interactions, catalytic efficiency, and reaction pathways, which are fundamental for designing novel catalytic systems. Dr. Jean Moto Ongagna’s research in computational catalysis, transition metal chemistry, and theoretical modeling aligns perfectly with the objectives of the “Catalysis Awards”. His work advances the understanding of catalyst behavior, reaction mechanisms, and molecular interactions, making a substantial impact on modern catalysis research. His ability to integrate quantum chemistry tools with catalytic design positions him as a highly suitable candidate for this prestigious recognition.

🎓Education:

Dr. Jean Moto Ongagna pursued his higher education at the University of Douala, Cameroon. He earned a Ph.D. in Theoretical and Computational Chemistry (2021), focusing on Density Functional Theory (DFT) and molecular simulations. In 2016, he completed his Master’s degree in the same field, where he explored the computational analysis of metal-ligand interactions. His Bachelor’s degree in Physical Chemistry (2013) laid the foundation for his research on quantum chemistry and molecular modeling. Before university, he completed his GCE Advanced Level (Baccalauréat D) in 2008 at Laic Private College “La Liberté” in Douala. His education equipped him with expertise in quantum chemistry, molecular docking, and theoretical modeling, enabling him to contribute to cutting-edge research. Throughout his academic journey, he attended specialized workshops and conferences to enhance his skills in computational chemistry, continuously refining his expertise in quantum simulations and advanced chemical theories.

🏢Work Experience:

Dr. Jean Moto Ongagna has extensive experience in Theoretical chemistry and Computational Chemistry, with expertise in Density Functional Theory (DFT), Molecular Docking, Pharmacokinetics (ADMET), and ab initio Molecular Dynamics (ADMP). He has actively participated in international conferences, presenting research on transition metal complexes, chemical bonding, and molecular interactions. He has contributed to significant projects involving the computational study of catalysts, biomolecular interactions, and pharmaceutical compounds. Dr. Ongagna has also collaborated with renowned institutions and researchers worldwide, publishing extensively in high-impact journals. His research experience includes developing and applying quantum chemical tools for investigating metal-ligand interactions and reaction mechanisms. He has been involved in multiple computational chemistry workshops, enhancing his knowledge of secondary metabolite discovery, quantum topology, and electronic structure theory. His contributions have led to a deeper understanding of non-standard chemical bonding and have implications for catalysis, drug design, and materials science.

🏅Awards:

Dr. Jean Moto Ongagna has received multiple recognitions for his contributions to Theoretical and Computational Chemistry. He has been invited as a speaker at international conferences, including the 4th Commonwealth Chemistry Posters (2023) and the Virtual Conference on Chemistry and Its Applications (2021, 2022). His research on transition metal complexes and quantum chemistry has been published in high-impact journals such as RSC Advances and the International Journal of Quantum Chemistry. He has received accolades for his computational investigations on catalytic and biomolecular systems, contributing to the advancement of quantum chemical methodologies. His participation in scientific workshops at the University of Buea (Cameroon) and Technische Universität Dresden (Germany) further highlights his academic excellence. His continuous engagement in international scientific discussions and collaborations has strengthened his reputation as a leading researcher in quantum chemistry and molecular modeling.

🔬Research Focus:

Dr. Jean Moto Ongagna’s research focuses on Theoretical and Computational Chemistry, particularly Density Functional Theory (DFT), Quantum Chemical Calculations, Molecular Docking, Pharmacokinetics (ADMET), and Molecular Dynamics (MD). He specializes in studying transition metal complexes, non-standard chemical bonds, and catalytic reactions. His work involves topological analysis of chemical interactions using advanced computational techniques such as Quantum Theory of Atoms in Molecules (QTAIM), Energy Decomposition Analysis (EDA), and Natural Bond Orbital (NBO) analysis. He has made significant contributions to understanding palladium complexes, Diels–Alder reactions, and bioactive compounds. His research extends to computational drug discovery, antimicrobial compounds, and bioinorganic chemistry, aiming to bridge the gap between theoretical modeling and experimental applications. By integrating quantum chemical methods with molecular simulations, his studies provide valuable insights into reaction mechanisms, electronic structures, and potential applications in pharmaceuticals, catalysis, and material science.

Publication Top Notes:

Deciphering the Influence of Alkylene Bridged and Chelating Mode on Pd—C and Pd—X (X = Cl, Br, and I) Bonding Interaction Within Bis‐(NHC)‐Palladium Complexes Using Quantum Chemistry Tools

Authors: Gaël Mouzong D’Ambassa, Jean Moto Ongagna, Adjieufack Abel Idrice, Désiré Bikele Mama

Year: 2024

Computational Exploration of the Impact of Low‐Spin and High‐Spin Ground State on the Chelating Ability of Dimethylglyoxime Ligand on Dihalo Transition Metal: A QTAIM, EDA, and CDA Analysis

Authors: Daniel Lissouck, Suzane Leonie Djendo Mazia, Gaël Mouzong D’Ambassa, Jean Moto Ongagna

Year: 2024

Deciphering the Influence of PdII and PdIV Oxidation States on Non-Standard Chemical Bonds Within Bis(N-Heterocyclic Carbene) Complexes: Insights from DFT

Authors: Gaël Mouzong D’Ambassa, Jean Moto Ongagna, Adjieufack Abel Idrice, Désiré Bikele Mama

Year: 2024

Exploring the Mechanism of the Intramolecular Diels–Alder Reaction of (2E,4Z,6Z)-2(allyloxy)cycloocta-2,4,6-trien-1-one Using Bonding Evolution Theory