Chuan-Jun Wang | Material Chemistry | Best Researcher Award

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Prof. Chuan-Jun Wang | Material Chemistry | Best Researcher Award

Professor from Shandong Agricultural University, China

Professor Wang Chuanjun is a distinguished academic and researcher currently serving at Shandong Agricultural University. With a deep-rooted background in chemistry and catalysis, his work primarily focuses on advancing sustainable energy solutions through photo- and electrocatalytic processes. Prof. Wang’s scholarly journey is marked by excellence and international collaboration, having undergone postdoctoral research at the Institute of Chemical Research of Catalonia (ICIQ) in Spain—a globally recognized hub for chemical innovation. His contributions span green catalysis, nitrogen conversion, and biomass valorization, all critical for a low-carbon future. He has published over 30 research articles in high-impact journals indexed in SCI and Scopus and has secured 6 patents, reflecting a strong translational aspect to his research. With a citation index exceeding 1800, his work is widely acknowledged by peers in the scientific community. Prof. Wang leads national and provincial projects focused on catalytic ammonia synthesis, showcasing his capacity to spearhead innovative and impactful research. His portfolio also includes participation in international collaborations and consultancies, adding depth to his academic profile. Passionate about scientific development and knowledge dissemination, Prof. Wang continues to drive meaningful progress in sustainable technologies and energy conversion systems.

Professional Profile

Education

Professor Wang Chuanjun’s academic foundation reflects a consistent pursuit of excellence in chemistry and material science. He began his undergraduate studies at Shandong Agricultural University (2006–2010), majoring in chemistry, where he laid the groundwork for his future in catalysis and green technology. He then advanced to the Technical Institute of Physics and Chemistry at the Chinese Academy of Sciences (TIPC-CAS), completing both his Master’s (2010–2012) and Doctoral (2012–2015) degrees. At TIPC-CAS, he specialized in electrochemical systems and advanced materials, gaining hands-on experience in catalytic reactions, particularly those involving nitrogen and hydrogen transformations. Eager to broaden his research perspective, Prof. Wang undertook a prestigious postdoctoral fellowship (2015–2018) at the Institut Català d’Investigació Química (ICIQ) in Tarragona, Spain. During this time, he engaged with world-leading researchers and technologies, deepening his expertise in molecular catalysis and photoinduced reactions. This international exposure has significantly influenced his methodological approach and innovation in his later projects. His academic path has been integral to shaping his current focus areas, including green catalysis, nanomaterial development, and electrocatalytic processes for sustainable energy solutions.

Professional Experience

Prof. Wang Chuanjun’s professional career is a testament to his dedication to scientific research and education. He has been a full-time Professor at Shandong Agricultural University since January 2019, where he teaches, supervises postgraduate research, and leads several national and provincial scientific projects. His current position allows him to explore catalytic solutions for global challenges, such as clean ammonia synthesis and nitrogen fixation, by integrating metal-based nanomaterials and advanced light-driven systems. Prior to this role, he served as a postdoctoral researcher at ICIQ, Spain (2015–2018), where he worked on photochemical and organometallic catalysis, gaining invaluable international exposure and enhancing his collaborative research skills. His time at ICIQ built a strong foundation in synthetic methodology and catalysis that he has since translated into practical, scalable energy applications in China. Earlier, as a graduate and doctoral student at the Technical Institute of Physics and Chemistry (TIPC-CAS), he conducted pioneering studies on electrochemical materials and reaction mechanisms. With experience that spans both academic institutions and cross-border scientific initiatives, Prof. Wang has developed a dynamic professional portfolio, combining teaching excellence with real-world research impact in energy science and sustainable chemistry.

Research Interests

Prof. Wang Chuanjun’s research interests are centered on catalysis-driven solutions for sustainable energy and environmental systems. His work focuses on the synthesis and application of nanostructured metal phosphides and transition metal complexes for photo- and electrocatalytic nitrogen conversion, aiming to produce ammonia and hydrogen under mild conditions. He is particularly interested in green catalysis strategies that mimic natural enzymatic processes, especially nitrogenase-like systems that enable low-energy nitrogen fixation. His work also explores biomass conversion, utilizing renewable sources for energy and chemical production. A core area of his research is the design of photocatalytic systems for enhanced solar-driven reactions, integrating light harvesting with catalytic processes for higher efficiency and selectivity. Additionally, Prof. Wang investigates the fundamental kinetics and mechanistic pathways involved in these transformations, leveraging spectroscopy and electrochemical analysis to refine catalytic designs. Through collaborations and interdisciplinary approaches, he aims to bridge material synthesis, reaction engineering, and environmental science. His research not only contributes to academic understanding but also has potential implications for industrial ammonia production and sustainable agricultural practices.

Research Skills

Prof. Wang Chuanjun possesses a diverse and robust set of research skills that span synthetic chemistry, catalysis, material characterization, and electrochemical analysis. He is highly proficient in the synthesis of nanostructured metal phosphides, transition metal complexes, and functionalized photocatalysts, which are central to his work on nitrogen fixation and hydrogen evolution. His expertise includes the use of advanced characterization techniques such as X-ray diffraction (XRD), scanning and transmission electron microscopy (SEM/TEM), and spectroscopy (UV-Vis, FTIR, NMR), which he employs to elucidate material structures and reaction mechanisms. In electrochemistry, he is adept in cyclic voltammetry, chronoamperometry, and electrochemical impedance spectroscopy, allowing detailed insights into charge transfer processes and catalytic activity. His skills also encompass computational modeling and mechanistic studies to simulate catalytic pathways and optimize energy efficiency. Prof. Wang’s research is strengthened by his ability to integrate lab-scale findings with scalable design, often considering industrial relevance and sustainability. His multidisciplinary competencies make him a versatile and forward-thinking scientist capable of addressing complex challenges in green chemistry and renewable energy technologies.

Awards and Honors

Throughout his career, Prof. Wang Chuanjun has been recognized for his contributions to the field of catalysis and green chemistry. He has received funding and honors from prominent institutions, including the Youth Project of the Natural Science Foundation of Shandong Province, where he serves as the project lead on electrocatalytic nitrate/nitrite reduction to ammonia. Additionally, he was awarded the Shandong Provincial High-level Foreign Experts Project to explore visible-light-driven synthesis of nanomaterials for nitrogen conversion—a prestigious recognition of his innovative research in sustainable materials. He also participated in the Shandong University Youth Talent Promotion Project on green catalysis and synthesis, further validating his expertise in eco-friendly chemical processes. Prof. Wang has published 33 papers in international peer-reviewed journals and has a citation index of over 1800, reflecting his scientific impact. He holds six patents and has provided consultancy services to industry, demonstrating the practical applicability of his work. These accolades underscore his leadership in the field and his commitment to developing next-generation technologies for energy and environmental sustainability.

Conclusion

Prof. Wang Chuanjun is an accomplished researcher whose work exemplifies innovation, sustainability, and academic rigor in the field of chemical catalysis. His academic background, international research experience, and ongoing leadership in multiple funded projects position him as a valuable contributor to the scientific community. With research spanning nitrogen conversion, biomass utilization, and green energy, Prof. Wang’s efforts address urgent global challenges in clean energy and environmental stewardship. His skillset integrates material science, electrochemical analysis, and catalytic system design, bridging fundamental research with real-world impact. The high citation index and patent record highlight both scholarly influence and practical relevance. While expanding editorial involvement and global scientific engagement could enhance his profile further, his current contributions already make him a strong candidate for high-level recognition. His leadership in provincial and international projects, combined with a commitment to academic excellence and interdisciplinary research, affirms his suitability for the Best Researcher Award. Prof. Wang represents the next generation of chemists driving transformative advances in sustainable science.

Publications Top Notes

  1. Hyaluronic acid-functionalized nanoarmor enhances the stable colonization ability of Paenibacillus polymyxa JF_P68 and boosts its biological control efficacy against pear anthracnose
    Journal: Pest Management Science, 2025
    Authors: Du, J.; Li, H.; Wu, L.; Liu, Y.; Sun, F.; Tian, X.; Lu, N.; Jiao, Y.; Liu, S.; Zhao, X.; Wang, C.-J.

  2. Synergistic Pd-CoFe sites for efficient and selective electrooxidation of glycerol to glyceric acid coupled with H₂ evolution
    Journal: Chemical Engineering Journal, 2025
    Authors: Zhou, J.; Shi, R.; Gao, Q.; Liu, F.; Chen, Y.; Chen, J.; Guo, Z.; Tse, E.C.M.; Zhao, X.; Wang, C.-J.

  3. Facile construction of CuFe-based metal phosphides for synergistic NOₓ⁻ reduction to NH₃ and Zn–nitrite batteries in electrochemical cell
    Journal: Small, 2024
    Authors: Wang, G.; Wang, C.; Liu, S.; Zhao, X.; Xu, J.; Tian, X.; Li, Q.; Waterhouse, G.I.N.

  4. Methane sulfonic acid-assisted synthesis of g-C₃N₄/Ni₂P/Ni foam: Efficient, stable and recyclable for photocatalytic nitrogen fixation under visible light
    Journal: Journal of Environmental Chemical Engineering, 2024
    Authors: Gao, X.; Zhang, B.; Cao, L.; Liu, F.; Fan, H.; Wang, C.; Xu, J.

  5. Visible light-driven synthesis of PtCu alloy nanodendrites for electrocatalytic nitrogen-conversion reactions
    Journal: Advanced Sustainable Systems, 2024
    Authors: Wang, G.; Wang, C.; Zhao, X.; Liu, S.; Zhang, Y.; Lv, X.; Xu, J.; Waterhouse, G.I.N.

  6. Glufosinate ammonium-loaded halloysite nanotubes for slow-release weeding polymer mulch films
    Journal: ACS Applied Nano Materials, 2023
    Authors: Jia, X.; Zhang, K.; Wang, C.; You, X.; Yang, S.; Wang, J.; Zhang, B.; Xu, J.; Yan, Y.; Wang, Y.

  7. CoP nanowires on carbon cloth for electrocatalytic NOₓ⁻ reduction to ammonia
    Journal: Journal of Electroanalytical Chemistry, 2022
    Authors: Zhang, H.; Wang, G.; Wang, C.; Liu, Y.; Yang, Y.; Jiang, W.; Fu, L.; Xu, J.

  8. Electrochemical ammonia synthesis from nitrite assisted by in situ generated hydrogen atoms on a nickel phosphide catalyst
    Journal: Chemical Communications, 2021
    Authors: Yang, X.; Liu, F.; Chen, Y.; Kang, L.; Wang, C.-J.

 

Prasenjit Das | Chemistry | Best Researcher Award

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Dr. Prasenjit Das | Chemistry | Best Researcher Award

Postdoc Researcher from Technische Universität Berlin, Germany

Dr. Prasenjit Das is an accomplished materials scientist with a focus on the design and synthesis of advanced materials for energy, sustainability, and environmental applications. His research primarily concentrates on the development of porous materials, such as covalent organic frameworks (COFs) and metal-organic frameworks (MOFs), for innovative solutions in energy storage, catalysis, and environmental remediation. With an impressive academic and professional background, Dr. Das has collaborated with leading global institutions and secured prestigious fellowships like the Alexander von Humboldt Fellowship. His contributions to the scientific community are marked by his ability to manage high-impact research projects, mentor students, and publish in top-tier journals. Known for his leadership in research and passion for education, Dr. Das is an emerging thought leader in advanced material science, with a vision for advancing sustainability through innovation. He continues to push the frontiers of materials research while nurturing the next generation of scientists.

Professional Profile

Education

Dr. Prasenjit Das holds an academic foundation that blends both theoretical knowledge and practical expertise. He obtained his Ph.D. in Chemistry from the University of Mumbai, where his dissertation focused on the synthesis and characterization of novel porous materials for catalytic and energy applications. During his postdoctoral work at the University of Pittsburgh, he expanded his research on the use of metal-organic frameworks (MOFs) in clean energy applications, particularly in CO2 capture and hydrogen storage. His educational journey is a reflection of his commitment to advancing the field of material science, combining deep academic rigor with practical innovation. This education has provided him with the necessary tools to contribute significantly to the scientific community and continue to lead in his area of expertise.

Professional Experience

Dr. Prasenjit Das has a diverse and extensive professional background, highlighted by his postdoctoral research at the Technical University of Berlin and the University of Pittsburgh, where he contributed to groundbreaking work in advanced materials and sustainability. His research expertise extends to catalysis, energy conversion, and environmental sustainability, focusing on the synthesis of novel materials like COFs and MOFs for critical applications. Dr. Das has also been an integral member of several internationally recognized research teams, overseeing research projects funded by prominent institutions such as DFG and UnisysCat. His professional roles have consistently demonstrated his leadership and ability to work collaboratively across disciplines. Dr. Das is currently leading cutting-edge projects that are aimed at addressing some of the most pressing global challenges in energy and sustainability.

Research Interests

Dr. Prasenjit Das’s research interests are primarily focused on developing advanced materials for energy storage, conversion, and environmental sustainability. He specializes in the synthesis of porous materials, including covalent organic frameworks (COFs) and metal-organic frameworks (MOFs), for use in clean energy applications such as CO2 capture, hydrogen storage, and photocatalysis. His work explores the intersection of material science, catalysis, and sustainability, aiming to create efficient and scalable solutions for energy-related challenges. Additionally, Dr. Das has a keen interest in the functionalization of porous materials for water splitting, renewable energy generation, and environmental protection. His research aims to bridge the gap between fundamental material science and its practical applications in addressing global issues such as climate change and resource depletion.

Research Skills

Dr. Prasenjit Das possesses a broad and diverse set of research skills that have allowed him to contribute significantly to the field of materials science. His expertise spans the synthesis and characterization of advanced porous materials, including COFs and MOFs, with a focus on their applications in energy storage, catalysis, and environmental sustainability. He is proficient in a wide array of analytical techniques, including X-ray diffraction (XRD), scanning electron microscopy (SEM), and nuclear magnetic resonance (NMR) spectroscopy, which he employs to thoroughly characterize and understand the properties of novel materials. Additionally, Dr. Das is skilled in computational modeling and simulation, which aids in the design and prediction of material behaviors. His strong leadership, mentoring abilities, and collaborative approach to research make him an invaluable asset to any research team.

Awards and Honors

Dr. Prasenjit Das has received several prestigious awards and honors throughout his career, recognizing his outstanding contributions to materials science and sustainability. Most notably, he was awarded the highly competitive Alexander von Humboldt Fellowship, which enabled him to further his research in advanced materials at leading international institutions. Additionally, his work has been recognized with several research grants from prominent funding bodies, including the Deutsche Forschungsgemeinschaft (DFG) and UnisysCat. Dr. Das has also been invited to present his research at numerous international conferences, further solidifying his position as an emerging leader in his field. His ability to secure funding and his collaborative efforts with global institutions highlight his potential for further recognition and success in the scientific community.

Conclusion

In conclusion, Dr. Prasenjit Das stands out as an innovative researcher with significant contributions to materials science and sustainability. His focus on the development of advanced porous materials, including COFs and MOFs, for energy and environmental applications, positions him as a leader in his field. Dr. Das’s ability to secure competitive fellowships, manage impactful research projects, and mentor the next generation of scientists highlights his exceptional leadership qualities. His work holds the potential to address pressing global challenges such as climate change and energy sustainability, making him a valuable asset to the scientific community. As he continues to make strides in his research, Dr. Das’s career is poised for even greater accomplishments in the coming years.

Publications Top Notes

  • Title: Nano‐Scale Anti‐Cancer Drug Delivery by a Zn‐Based Metal Organic Framework Carrier
    Authors: P. Das, G. Chakraborty, J. Kaur, S.K. Mandal
    Journal: Small, 2408810
    Year: 2025

  • Title: Decoding Dual‐Functionality in N‐doped Defective Carbon: Unveiling Active Sites for Bifunctional Oxygen Electrocatalysis
    Authors: S. Bhardwaj, A. Pathak, S.K. Das, P. Das, R. Thapa, R.S. Dey
    Journal: Small, 2411035
    Year: 2025

  • Title: Synthesis of Doped g‐C₃N₄ Photonic Crystals for Enhanced Light‐Driven Hydrogen Production from Catalytic Water‐Splitting
    Authors: S.Y. Djoko T., S. Kwon, P. Das, V. Weigelt, W. Tahir, B. Radhakrishnan, …
    Journal: Advanced Energy and Sustainability Research 5 (12), 2400181
    Year: 2024

  • Title: Two-Dimensional Covalent Organic Frameworks: Structural Insights across Different Length Scales and Their Impact on Photocatalytic Efficiency
    Authors: I.E. Khalil, P. Das, A. Thomas
    Journal: Accounts of Chemical Research 57 (21), 3138–3150
    Year: 2024
    Citations: 9

  • Title: Hierarchical Porous Covalent Organic Frameworks: The Influence of Additional Macropores on Photocatalytic Hydrogen Evolution and Hydrogen Peroxide Production
    Authors: I.E. Khalil, P. Das, H. Küçükkeçeci, V. Dippold, J. Rabeah, W. Tahir, …
    Journal: Chemistry of Materials 36 (17), 8330–8337
    Year: 2024
    Citations: 8

  • Title: The Effect of Pore Functionality in Multicomponent Covalent Organic Frameworks on Stable Long‐Term Photocatalytic H₂ Production
    Authors: P. Das, G. Chakraborty, J. Yang, J. Roeser, H. Küçükkeçeci, A.D. Nguyen, …
    Journal: Advanced Energy Materials, 2501193
    Year: 2024
    Citations: 1

  • Title: Heteropolyaromatic Covalent Organic Frameworks via One-Pot Multicomponent Reactions
    Authors: P. Das, G. Chakraborty, N. Friese, J. Roeser, C. Prinz, F. Emmerling, …
    Journal: Journal of the American Chemical Society 146 (25), 17131–17139
    Year: 2024
    Citations: 9

  • Title: Reversible Solvent Interactions with UiO-67 Metal–Organic Frameworks
    Authors: E.B. Isabella Goodenough, M.C. Boyanich, R.P. McDonnell, L. McDonnell, …
    Journal: The Journal of Chemical Physics 160 (4)
    Year: 2024
    Citations: 3

  • Title: Zeolitic MOFs Get a Facelift
    Authors: N.L. Rosi, P. Das
    Journal: Nature Synthesis 3 (1), 5–6
    Year: 2024
    Citations: 1

  • Title: Polyoxometalate (POM) Boosting the Light-Harvesting Ability of Graphitic Carbon Nitride for Efficient Photocatalytic Hydrogen Production
    Authors: E. Njoyim, A.D. Nguyen, J. Yang, H. Küçükkeçeci, E.M. Kutorglo, …
    Journal: Catalysis Science & Technology 14 (8), 2114–2129
    Year: 2024
    Citations: 3

Shaotao BAI | Chemistry | Best Researcher Award

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Prof. Shaotao BAI | Chemistry | Best Researcher Award

Professor from Shenzhen Polytechnic University, China

Professor Shaotao Bai is a distinguished academic and researcher specializing in sustainable catalysis and engineering. He currently serves as a Principal Investigator, Assistant Dean, and Director of the Center for Carbon-Neutrality Catalysis and Engineering at Shenzhen Polytechnic University. His work focuses on applied homogeneous and heterogeneous catalysis, computational catalysis, and the development of innovative solutions for CO₂ capture and utilization. With a robust background in both theoretical and practical aspects of catalysis, Professor Bai has made significant contributions to advancing carbon-neutral technologies. His research has been widely recognized and has had a substantial impact on the field of sustainable energy.

Professional Profile

Education

Professor Bai’s academic journey laid a solid foundation for his career in catalysis and sustainable engineering. He earned his doctoral degree in a field pertinent to his current research focus, equipping him with the necessary knowledge and skills to excel in both academic and professional settings. His education emphasized the principles of chemical engineering and catalysis, providing him with a comprehensive understanding of the mechanisms and applications of catalytic processes. This strong educational background has been instrumental in his ability to lead cutting-edge research projects and contribute meaningfully to the scientific community.

Professional Experience

In his current role at Shenzhen Polytechnic University, Professor Bai holds multiple leadership positions, including Principal Investigator, Assistant Dean, and Director of the Center for Carbon-Neutrality Catalysis and Engineering. These roles involve overseeing research initiatives, managing academic programs, and leading efforts to develop sustainable catalytic processes. Prior to this, he gained valuable experience in various academic and research institutions, where he honed his expertise in applied catalysis and computational methods. His professional journey reflects a consistent commitment to advancing the field of catalysis and addressing global challenges related to carbon emissions and energy sustainability.

Research Interests

Professor Bai’s research interests are centered around sustainable catalysis and engineering, with a particular focus on carbon-neutral technologies. He is deeply engaged in the development of both homogeneous and heterogeneous catalytic systems aimed at efficient CO₂ capture and utilization. Additionally, his work encompasses computational catalysis, where he employs theoretical models to predict and optimize catalytic behaviors. By integrating experimental and computational approaches, Professor Bai strives to design innovative solutions that contribute to reducing carbon footprints and promoting environmental sustainability.

Research Skills

With a comprehensive skill set in catalysis and engineering, Professor Bai excels in both experimental and computational methodologies. His expertise includes designing and synthesizing catalytic materials, conducting kinetic studies, and utilizing advanced computational tools to model catalytic processes. This combination of skills enables him to approach research problems from multiple angles, facilitating the development of efficient and sustainable catalytic systems. His proficiency in bridging theoretical concepts with practical applications has been a key factor in his successful research endeavors.

Awards and Honors

Throughout his career, Professor Bai has received several accolades recognizing his contributions to the field of catalysis and sustainable engineering. These honors reflect his dedication to research excellence and his impact on advancing carbon-neutral technologies. While specific awards are not detailed in the available information, his leadership roles and professional achievements underscore the esteem in which he is held by the academic and scientific communities.

Conclusion

Professor Shaotao Bai’s career exemplifies a profound commitment to addressing environmental challenges through innovative research in catalysis and engineering. His leadership at Shenzhen Polytechnic University, combined with his extensive expertise in both experimental and computational approaches, positions him at the forefront of efforts to develop sustainable solutions for CO₂ capture and utilization. As the global community continues to prioritize carbon neutrality, Professor Bai’s work remains instrumental in driving progress toward a more sustainable and environmentally responsible future.

Publications Top Notes​

  1. Title: Homogeneous and heterogeneous catalysts for hydrogenation of CO₂ to methanol under mild conditions
    Authors: S.T. Bai, G. De Smet, Y. Liao, R. Sun, C. Zhou, M. Beller, B.U.W. Maes, B.F. Sels
    Journal: Chemical Society Reviews
    Year: 2021
    Citations: 265

  2. Title: Heterogeneous catalysts for CO₂ hydrogenation to formic acid/formate: from nanoscale to single atom
    Authors: R. Sun, Y. Liao, S.T. Bai, M. Zheng, C. Zhou, T. Zhang, B.F. Sels
    Journal: Energy & Environmental Science
    Year: 2021
    Citations: 229

  3. Title: Hydrogen Bond Directed ortho-Selective C−H Borylation of Secondary Aromatic Amides
    Authors: S.T. Bai, C.B. Bheeter, J.N.H. Reek
    Journal: Angewandte Chemie International Edition
    Year: 2019
    Citations: 73

  4. Title: Lignin‐first monomers to catechol: rational cleavage of C−O and C−C bonds over zeolites
    Authors: X. Wu, Y. Liao, J. Bomon, G. Tian, S.T. Bai, K. Van Aelst, Q. Zhang, et al.
    Journal: ChemSusChem
    Year: 2022
    Citations: 37

  5. Title: A 13-million turnover-number anionic Ir-catalyst for a selective industrial route to chiral nicotine
    Authors: C. Yin, Y.F. Jiang, F. Huang, C.Q. Xu, Y. Pan, S. Gao, G.Q. Chen, X. Ding, S.T. Bai, et al.
    Journal: Nature Communications
    Year: 2023
    Citations: 35

  6. Title: Rhodium‐Catalyzed Chemo‐, Regio‐ and Enantioselective Hydroformylation of Cyclopropyl‐Functionalized Trisubstituted Alkenes
    Authors: S. Li, D. Zhang, R. Zhang, S.T. Bai, X. Zhang
    Journal: Angewandte Chemie International Edition
    Year: 2022
    Citations: 20

  7. Title: Rational redesign of a regioselective hydroformylation catalyst for 3‐butenoic acid by supramolecular substrate orientation
    Authors: S.T. Bai, V. Sinha, A.M. Kluwer, P.R. Linnebank, Z. Abiri, B. de Bruin, J.N.H. Reek
    Journal: ChemCatChem
    Year: 2019
    Citations: 20

  8. Title: Effector responsive hydroformylation catalysis
    Authors: S.T. Bai, V. Sinha, A.M. Kluwer, P.R. Linnebank, Z. Abiri, P. Dydio, M. Lutz, et al.
    Journal: Chemical Science
    Year: 2019
    Citations: 17

  9. Title: Suppressing Dormant Ru States in the Presence of Conventional Metal Oxides Promotes the Ru-MACHO-BH-Catalyzed Integration of CO₂ Capture and …
    Authors: S.T. Bai, C. Zhou, X. Wu, R. Sun, B. Sels
    Journal: ACS Catalysis
    Year: 2021
    Citations: 16

  10. Title: Synthesis of novel N-glycoside derivatives via CuSCN-catalyzed reactions and their SGLT2 inhibition activities
    Authors: S.T. Bai, D.C. Xiong, Y. Niu, Y.F. Wu, X.S. Ye
    Journal: Tetrahedron
    Year: 2015
    Citations: 16

  11. Title: Effector enhanced enantioselective hydroformylation
    Authors: S.T. Bai, A.M. Kluwer, J.N.H. Reek
    Journal: Chemical Communications
    Year: 2019
    Citations: 10

Svitlana Orlyk | Physical Chemistry | Best Researcher Award

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Prof. Svitlana Orlyk | Physical Chemistry | Best Researcher Award

Lead Scientist from L.V. Pisarzhevsky Institute of Physical Chemistry of NAS of Ukraine, Ukraine

Professor Svitlana M. Orlyk is a distinguished chemist specializing in catalytic redox processes, environmental catalysis, and hydrogen energy. She has made significant contributions to the development of advanced catalysts for pollution control, fuel reforming, and greenhouse gas conversion. With over four decades of experience, she has held key leadership positions at the L.V. Pisarzhevsky Institute of Physical Chemistry of NASU, where she currently serves as the Head of the Department of Catalytic Redox Processes. Professor Orlyk has authored more than 370 scientific publications, including over 200 peer-reviewed articles and 23 patents. Her research has been featured in multiple international monographs, highlighting her impact on the global scientific community. She has received prestigious awards, including the State Prize of Ukraine in Science and Technology and the Order of Princess Olga. Her expertise in heterogeneous catalysis, reaction kinetics, and catalyst design has led to innovative solutions for industrial and environmental challenges. Through her leadership and mentorship, she continues to drive advancements in catalysis, supporting the next generation of researchers in the field.

Professional Profile

Education

Professor Orlyk’s academic journey began at Kyiv Polytechnic Institute, where she earned a degree in Chemical Technology, specializing in Basic Processes of Chemical Production and Chemical Cybernetics in 1976. She pursued postgraduate studies in Chemical Kinetics and Catalysis at the L.V. Pisarzhevsky Institute of Physical Chemistry of NASU, completing her Ph.D. in 1982. Her doctoral research focused on catalytic reactions, laying the foundation for her future contributions to environmental catalysis and hydrogen energy. In 1998, she obtained a Doctor of Chemical Sciences degree from the same institute, marking a significant milestone in her academic career. Recognized for her expertise, she was appointed as a Professor in Chemical Kinetics and Catalysis in 2009. Her educational background has provided her with a strong foundation in chemical reaction engineering, catalyst design, and kinetic modeling. Through continuous learning and research, she has established herself as a leader in the field, contributing to both theoretical advancements and practical applications in catalysis. Her commitment to education extends to mentoring students and young researchers, ensuring the growth and sustainability of catalytic science in Ukraine and beyond.

Professional Experience

Professor Orlyk has had a progressive and impactful career in chemical research, spanning over 40 years. She began her professional journey as an Engineer in 1976 before transitioning into research, working as a Junior Scientific Associate from 1982 to 1986. Her expertise and dedication led to her promotion as a Scientific Associate (1986-1988), followed by Senior Scientist (1988-1999). Between 1999 and 2000, she served as a Lead Scientist, contributing significantly to catalytic reaction mechanisms and industrial applications of catalysts. In 2000, she was appointed as the Head of the Department of Catalytic Redox Processes at the L.V. Pisarzhevsky Institute of Physical Chemistry of NASU, a role she continues to hold. Under her leadership, the department has made significant advancements in catalyst design for environmental and industrial applications. Her work has influenced the development of efficient catalytic systems for pollution reduction, energy production, and sustainable chemistry. Throughout her career, she has collaborated with numerous researchers and institutions, further expanding the reach of her work in the international scientific community.

Research Interests

Professor Orlyk’s research focuses on the physicochemical principles of catalytic processes, particularly in environmental catalysis, hydrogen energy, and sustainable chemical production. She specializes in the kinetics and mechanisms of heterogeneous catalytic redox reactions, including those involving nitrogen oxides, carbon compounds, sulfur species, hydrocarbons, and oxygenates. Her work is aimed at designing next-generation catalysts for critical industrial applications, such as neutralizing harmful emissions (CO, NOx, hydrocarbons), reforming hydrocarbon fuels, and converting greenhouse gases (CO₂, CH₄, N₂O) into valuable chemicals. She is also actively involved in developing bifunctional catalysts for tandem processes that produce essential organic compounds from C1-C4 alkanes and bioalcohols. By integrating fundamental reaction mechanisms with practical catalyst development, her research contributes to both scientific innovation and environmental sustainability. Her investigations into advanced catalytic materials, including zeolites and cerium-based nanocatalysts, have led to breakthroughs in cleaner industrial processes and energy-efficient technologies.

Research Skills

Professor Orlyk possesses a diverse set of research skills in catalytic science, including catalyst synthesis, kinetic modeling, surface chemistry analysis, and reaction mechanism elucidation. She is proficient in designing and characterizing heterogeneous catalysts using advanced spectroscopic and microscopic techniques. Her expertise in chemical kinetics allows her to develop predictive models for catalytic reactions, optimizing performance for industrial applications. She has extensive experience with gas-phase and liquid-phase catalytic processes, particularly in environmental catalysis and energy conversion. Her work involves the integration of computational chemistry with experimental data to enhance catalyst efficiency and selectivity. She is also skilled in patent development, having secured 23 patents related to innovative catalytic materials and processes. Her ability to translate fundamental research into practical applications demonstrates her strength in bridging scientific discovery with industrial needs. Additionally, her leadership in research project management and mentorship highlights her commitment to advancing the field of catalysis through collaboration and knowledge dissemination.

Awards and Honors

Professor Orlyk’s contributions to catalysis and chemical sciences have been recognized through numerous prestigious awards. In 2000, she received the L.V. Pisarzhevsky Award of NAS of Ukraine for her research on selectivity in complex catalytic reactions. Her outstanding contributions to surface chemistry and catalysis earned her the State Prize of Ukraine in Science and Technology in 2008, acknowledging her work on adsorbed layers on transition metal surfaces. In recognition of her scientific achievements and service to Ukraine’s research community, she was awarded the Order of Princess Olga in 2019, one of the highest honors for distinguished women in science and academia. Beyond these national recognitions, her extensive publication record and inclusion in international monographs highlight her impact on the global scientific stage. Her achievements reflect a lifelong dedication to advancing catalysis for environmental sustainability and industrial efficiency.

Conclusion

Professor Svitlana M. Orlyk is a leading expert in catalytic redox processes, with an outstanding career dedicated to environmental catalysis, hydrogen energy, and sustainable chemical production. Her extensive research, leadership, and mentorship have significantly contributed to advancements in catalyst design and reaction kinetics. With over 370 scientific publications, numerous awards, and a strong record of innovation, she stands as a prominent figure in the field of chemistry. Her ability to combine fundamental research with industrial applications has led to impactful solutions for pollution control and energy efficiency. While her international collaborations and industry partnerships could be further strengthened, her current contributions already position her as an exceptional researcher. As Head of the Department of Catalytic Redox Processes, she continues to drive scientific progress and mentor the next generation of chemists, ensuring the sustainability of catalytic science. Her dedication, expertise, and accomplishments make her a highly deserving candidate for recognition as a top researcher in her field.

Publication Top Notes

  1. Vapor-Phase Carbonylation of Methanol with the Obtaining of Acetyls on Solid-Phase Catalysts: A Review

    • Authors: A.Y. Kapran, Y.I. Pyatnitsky, V.I. Chedryk, S.M. Orlyk
    • Year: 2024

  2. Effect of Surface Acidity/Basicity of Cr/Zn−BEA Zeolite Catalysts on Performance in CO₂-PDH Process

    • Authors: S.M. Orlyk, A.Y. Kapran, V.I. Chedryk, Y.M. Nychiporuk, P.I. Kyriienko, S. Dzwigaj
    • Year: 2024
    • Citations: 3

  3. Influence of Chromium in Cr/Zn-BEA Metal–Zeolite Composites on Their Acid–Base Characteristics and Catalytic Properties in the Processes of Propane Dehydrogenation

    • Authors: S.M. Orlyk, N.V. Vlasenko, V.I. Chedryk, A.Y. Kapran, S. Dzwigaj
    • Year: 2024

  4. The Effect of Modification of Zn–Mg(Zr)Si Oxide Catalysts with Rare-Earth Elements (Y, La, Ce) in the Ethanol-to-1,3-Butadiene Process

    • Authors: O.V. Larina, O.V. Zikrata, L.M. Alekseenko, S.O. Soloviev, S.M. Orlyk
    • Year: 2023

  5. Fast Synthesis of MgO–Al₂O₃ Systems: Effect on Physicochemical Characteristics and Catalytic Properties in Guerbet Condensation of Ethanol

    • Authors: K.V. Valihura, O.V. Larina, P.I. Kyriienko, S.O. Soloviev, S.M. Orlyk
    • Year: 2023
    • Citations: 1

  6. CO₂-Assisted Dehydrogenation of Propane to Propene over Zn-BEA Zeolites: Impact of Acid–Base Characteristics on Catalytic Performance

    • Authors: S.M. Orlyk, P.I. Kyriienko, A.Y. Kapran, V.I. Chedryk, D. Balakin, J. Gurgul, M. Zimowska, Y. Millot, S. Dzwigaj
    • Year: 2023
    • Citations: 11

  7. Catalytic Properties and Resource Characteristics of Modified Nickel Composites in the Processes of Oxidative Reforming of C₁-C₄ Alkanes

    • Authors: S.M. Orlyk, V.I. Chedryk, S.O. Soloviev, O.D. Vasylyev
    • Year: 2022

  8. Effect of Acid–Base Characteristics of Zeolite Catalysts on Oxidative Dehydrogenation of Propane with Carbon Dioxide

    • Authors: A.Y. Kapran, S.M. Orlyk
    • Year: 2022
    • Citations: 1