Mrs. Mercedes Bertotto | Organic Chemistry | Women Researcher Award

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Mrs. Mercedes Bertotto | Organic Chemistry | Women Researcher Award

Mrs. Mercedes Bertotto , Organic Chemistry , Researcher in Chemometrics at Wageningen University & Research , Netherlands

Dr. Mercedes Bertotto is a distinguished chemical engineer and food scientist with over 12 years of specialized experience in spectroscopic techniques, chemometrics, and quality control. Based in The Netherlands, she is currently a lecturer at Wittenborg University of Applied Sciences and founder of Vibralytics.nl, promoting sustainable and data-driven innovations in the agri-food sector. Previously, she was a researcher at Wageningen Food and Biobased Research, where she led spectral sensing projects integrating NIR, MIR, and Raman spectroscopy with machine learning. Her earlier role at SENASA, Argentina’s National Reference Laboratory, showcased her leadership in GC-MS residue analysis and chemometric modeling. Fluent in English, Spanish, and Dutch, Dr. Bertotto bridges scientific excellence with cross-cultural communication, driving sustainable solutions in food safety and circular materials. Her contributions to academia, research, and entrepreneurship reflect a strong commitment to innovation, international collaboration, and applied chemical sciences.

Professional Profile : 

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Summary of Suitability for Award:

Dr. Mercedes Bertotto stands out as an exceptionally qualified candidate for the “Women Researcher Award” due to her profound scientific expertise, leadership, and innovation across multiple sectors. With a Doctorate in Chemical Engineering and a strong academic foundation in Food Science and Technology, she exemplifies excellence in applied and theoretical research. Her 12+ years of impactful work—from Argentina’s SENASA National Reference Laboratory to the Netherlands’ Wageningen Food and Biobased Research—reflect her global research footprint. She has made significant contributions in spectral sensing, chemometrics, machine learning, and food quality control. Moreover, her entrepreneurial initiative as the founder and CEO of Vibralytics.nl demonstrates her commitment to translating science into real-world, sustainable solutions. Dr. Mercedes Bertotto is highly suitable for the “Women Researcher Award’. Her multidisciplinary achievements, pioneering role in spectral analytics, dedication to sustainable food systems, and entrepreneurial leadership in a male-dominated field exemplify the qualities the award seeks to recognize. Her career reflects not only scientific merit but also her inspirational impact as a woman in science, making her a deserving and empowering candidate for this honor.

🎓Education:

Dr. Bertotto holds a Doctorate in Chemical Engineering from the University of Buenos Aires, where her thesis focused on modeling drying and tempering processes of rice (IRGA 424). Her research included dynamic mechanical analysis and mathematical modeling of glass transition temperature, achieving an outstanding score of 10/10. She also holds a Master’s in Food Science and Technology from the Faculty of Pharmacy and Biochemistry, University of Buenos Aires. Her academic formation enabled her to work on food preservation, quality control, and raw material analysis using both physical and chemical techniques. Her educational foundation is rooted in experimental precision, mathematical rigor, and industrial application. This robust background has allowed her to seamlessly bridge theory with practical laboratory and industry-based problem-solving. Her education reflects interdisciplinary training, combining engineering, food science, and analytical chemistry—providing her with the ideal base for impactful research in sustainable biobased materials and food safety.

🏢Work Experience:

Dr. Bertotto brings an extensive and diverse professional background. She currently lectures in Information Management and Data Analytics at Wittenborg University and leads Vibralytics.nl, a company pioneering AI-driven spectroscopy for agri-food applications. Between 2022–2024, she was a spectral sensing researcher at Wageningen Food and Biobased Research, using hyperspectral imaging and chemometrics (PCA, PLS, CNN) for quality control. From 2010 to 2022, she worked at SENASA in Argentina, specializing in NIR/FTIR microscopy, GC-MS, and regulatory compliance in food safety. As a university professor, she taught chemometric tools for doctoral candidates, and she also served as a consultant at SoftLab, contributing to petroleum industry applications of NIR. Her expertise encompasses spectroscopy hardware (Specim FX10/17, MicroNIR, LabSpec), data tools (R, MATLAB), and AI-based modeling. This blend of research, teaching, and consulting makes her a well-rounded scientist, with real-world and academic impact across multiple industries.

🏅Awards: 

While specific awards are not explicitly listed, Dr. Mercedes Bertotto’s recognitions include multiple peer-reviewed publications, oral and poster presentations at prestigious conferences, and leadership roles in top-tier research institutions like Wageningen University. Her work was accepted for presentation at the 38th EFFoST International Conference (2024) and ICNIRS 2023, both internationally acclaimed events in food science and spectroscopy. She has also contributed to publicly recognized innovation efforts in Argentina, featured in national science communications (e.g., Argentina.gob.ar and API-Portal). Her appointment as a doctoral-level professor and selection as a founder and CEO of a research-driven company demonstrates academic and entrepreneurial recognition. Moreover, her trilingual fluency and international engagement serve as indicators of her global scientific outreach and influence. These distinctions—academic, institutional, and professional—reflect her commitment to innovation, research excellence, and interdisciplinary problem-solving in chemical engineering and food safety.

🔬Research Focus:

Dr. Bertotto’s research is grounded in analytical chemistry, spectral sensing, and chemometric modeling applied to food and agricultural systems. Her focus lies in leveraging Near-Infrared (NIR), Mid-Infrared (MIR), FTIR microscopy, Raman spectroscopy, and gas chromatography-mass spectrometry (GC-MS) to improve food quality, detect contaminants, and enable circular and sustainable material flows. She specializes in multivariate analysis (PCA, PLS-DA, ANN, CNN) for interpreting complex spectral data in real-time monitoring systems. Her work integrates hyperspectral imaging with AI-driven tools to predict physical and chemical properties of biological materials, such as fungal susceptibility in tomatoes or nutrient profiling in dairy. She is also deeply involved in modeling moisture and thermal behavior in grains like rice. Her research bridges fundamental science with applied industry solutions—creating novel analytical frameworks that optimize safety, quality, and sustainability in bio-based materials, food systems, and environmental monitoring.

Publication Top Notes:

1. Predicting fungal infection sensitivity of sepals in harvested tomatoes using imaging spectroscopy and partial least squares discriminant analysis

2. Comparison between Chemometrics and Machine Learning for the Prediction of Macronutrients in Fresh Cheeses Using Imaging Spectroscopy

3. Detection of Animal By‑Products in Bone Ashes by Near Infrared Spectroscopy Coupled with Microscopy

  citation : 1

 

 

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

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

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

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

Professional Profile :         

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Summary of Suitability for Award:

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

🎓Education:

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

🏢Work Experience:

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

🏅Awards: 

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

🔬Research Focus:

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

Publication Top Notes:

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

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

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

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

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

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

Selective Synthesis of Sulfonamides and Sulfenamides from Sodium Sulfinates and Amines

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

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

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

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

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

 

Assoc. Prof. Dr. Paresh Patel | Organic Chemistry | Best Researcher Award

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Assoc. Prof. Dr. Paresh Patel | Organic Chemistry | Best Researcher Award

Assoc. Prof. Dr. Paresh Patel , Uka Tarsadia University , India

Dr. Paresh N. Patel, is an Indian chemist and academic leader, currently serving as the I/c Director of the Tarsadia Institute of Chemical Science, Uka Tarsadia University, Gujarat. With over 12 years of experience in teaching, research, and administration, Dr. Patel has significantly contributed to organic synthesis, nanotechnology, and bio-sensor development. He has authored 42 peer-reviewed publications, holds five patents, and supervised numerous MSc and PhD scholars. As an editor and reviewer for reputed journals, he actively engages in the scientific community. Dr. Patel has been instrumental in securing several high-value research grants, collaborating with academia and industry to advance chemical sciences.

Professional Profile

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Summary of Suitability for Award:

Dr. Paresh N. Patel is an accomplished researcher with a prolific career spanning over a decade in chemical sciences. His expertise lies in organic synthesis, nanotechnology, and biosensor development, supported by 42 international publications, five patents, and significant research grants totaling over ₹3 crore. He has successfully led and collaborated on high-impact projects funded by prestigious organizations such as DST, GUJCOST, GSBTM, and DBT, demonstrating his ability to secure competitive funding and deliver innovative outcomes. Dr. Paresh N. Patel’s exceptional achievements, diverse research portfolio, and impactful contributions make him highly suitable for the “Best Researcher Award.” His innovative work has advanced the frontiers of chemical sciences and demonstrated practical relevance, aligning with the award’s objective of recognizing excellence in research.

🎓Education:

Dr. Paresh N. Patel completed his PhD in Organic Synthesis from Sardar Patel University in 2013, after earning an MSc in Organic Chemistry (2009) and a BSc in Chemistry (2007) from the same institution. His academic training provided a robust foundation for his research in asymmetric synthesis, nanomaterials, and renewable resources. During his doctoral studies, he specialized in single-crystal X-ray diffraction and advanced organic methodologies. He also received an Institute Postdoctoral Fellowship at IIT Madras, where he further honed his expertise in heterocyclic compound synthesis. Over his academic journey, Dr. Patel has consistently demonstrated academic excellence, evident in his comprehensive research output and accolades for innovation.

🏢Work Experience:

Dr. Paresh N. Patel has an illustrious career spanning academia and research. He has served as an I/c Director at Tarsadia Institute of Chemical Science since 2019 and was promoted to Associate Professor in 2024. Previously, he was an Assistant Professor (2016–2024) at Uka Tarsadia University and a Postdoctoral Fellow at IIT Madras (2013–2016), contributing to teaching and research in organic chemistry. He has also worked as a Fellow at NIF-Ahmedabad and an SRF at Sardar Patel University. His roles have encompassed teaching spectroscopy, nanotechnology, and stereochemistry, as well as guiding MSc, PhD, and Postdoctoral scholars. Dr. Patel’s leadership in organizing scientific events and workshops reflects his dedication to fostering innovation and skill development in chemical sciences.

🏅Awards: 

Dr. Paresh N. Patel has earned numerous accolades for his contributions to chemical research. He was awarded the prestigious DST Inspire Grant (₹24 lakh) and several significant project grants, including ₹30 lakh from GUJCOST and ₹32 lakh from GSBTM. He also received an International Travel Grant from DBT to present his research in the USA and was a recipient of a ₹10 lakh ICSR-IIT Madras project fund. His excellence in academia has been recognized through various seed grants from Uka Tarsadia University and industrial-funded research projects. Additionally, his proposals under DST-SYST and DST-TDP are under consideration, with a substantial ₹3 crore DST-FIST project in preparation. These accolades highlight Dr. Patel’s commitment to advancing scientific knowledge and fostering impactful collaborations.

🔬Research Focus:

Dr. Paresh N. Patel’s research centers on innovative applications of organic chemistry and nanotechnology. His projects include developing nano-scale organic biosensors (DST-SERB) and synthesizing gold nanoparticles from renewable resources for organic synthesis (GSBTM). He also explores asymmetric synthesis using biocatalysts and collaborates with industry to develop biotechnology for hydrogen and ethanol production. His research portfolio includes several high-value grants, such as DST Inspire, GUJCOST, and GSBTM. Dr. Patel’s interdisciplinary approach integrates materials science, biotechnology, and organic chemistry, aiming to address environmental and industrial challenges. His work not only advances theoretical understanding but also offers practical solutions in chemical and biosensor technology.

Publication Top Notes:

Title: Study of lawsone and its modified disperse dyes derived by triple cascade reaction: dyeing performance on nylon and polyester fabrics
Authors: Patel, N.C., Desai, D.H., Patel, P.N.
Year: 2024
Citations: 2

Title: Selective detection of azelnidipine in pharmaceuticals via carbon dot mediated spectrofluorimetric method: A green approach
Authors: Lodha, S.R., Gore, A.H., Merchant, J.G., Shah, S.A., Shah, D.R.
Year: 2024
Citations: 1

Title: Benzothiophene based semi-bis-chalcone as a photo-luminescent chemosensor with real-time hydrazine sensing and DFT studies
Authors: Oza, N.H., Kasundra, D., Deshmukh, A.G., Boddula, R., Patel, P.N.
Year: 2024
Citations: 0

Title: A lawsone based novel disperse dyes with DHPMs scaffold: dyeing studies on nylon and polyester fabric
Authors: Patel, N.C., Talati, K.S., Patel, P.N.
Year: 2024
Citations: 0

Title: Surface functionalized graphene oxide integrated 9,9-diethyl-9H-fluoren-2-amine monohybrid nanostructure: Synthesis, physicochemical, thermal and theoretical approach towards optoelectronics
Authors: Borane, N., Boddula, R., Odedara, N., Jirimali, H., Patel, P.N.
Year: 2024
Citations: 1

Title: Fungus reinforced sustainable gold nanoparticles: An efficient heterogeneous catalyst for reduction of nitro aliphatic, aromatic and heterocyclic scaffolds
Authors: Deshmukh, A.G., Rathod, H.B., Patel, P.N.
Year: 2023
Citations: 1

Title: Green and sustainable bio-synthesis of gold nanoparticles using Aspergillus Trinidadensis VM ST01: Heterogeneous catalyst for nitro reduction in water
Authors: Deshmukh, A.G., Mistry, V., Sharma, A., Patel, P.N.
Year: 2023
Citations: 3

Title: Design and synthesis of chalcone mediated novel pyrazoline scaffolds: Discovery of benzothiophene comprising antimicrobial inhibitors
Authors: Tandel, S.N., Kasundra, D.V., Patel, P.N.
Year: 2023
Citations: 2

Title: Studies of novel benzofuran based chalcone scaffolds: A dual spectroscopic approach as selective hydrazine sensor
Authors: Tandel, S.N., Deshmukh, A.G., Rana, B.U., Patel, P.N.
Year: 2023
Citations: 4

Title: Novel chalcone scaffolds of benzothiophene as an efficient real-time hydrazine sensor: Synthesis and single crystal XRD studies
Authors: Tandel, S.N., Mistry, P., Patel, P.N.
Year: 2023
Citations: 4

 

 

 

Dr. Mukti Tyagi | Organic Chemistry Award | Best Researcher Award

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Dr. Mukti Tyagi | Organic Chemistry Award | Best Researcher Award

Dr. Mukti Tyagi , Shriram institute for industrial research , India

Dr. Mukti Tyagi is an Assistant Scientist ‘A’ at Shriram Institute for Industrial Research, Delhi. With over 15 years of research experience, Dr. Tyagi specializes in polymer synthesis, characterization, and modification for various industrial applications. Her work has led to advancements in optical materials, including metal-containing polymers and nanocomposites, and she has contributed to projects related to optical lenses, seed coatings, and smart materials. Her expertise spans both academic research and industrial development, with notable contributions to the fields of chemistry and materials science. Dr. Tyagi has published extensively in peer-reviewed journals and has presented her work at international conferences. She has also been involved in several research projects funded by BRNS, DRDO, and other agencies. Her dedication to advancing polymer science has earned her significant recognition in the field.

Professional Profile:

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Summary of Suitability for Award:

Dr. Mukti Tyagi’s extensive research background, impactful publications, significant patents, and contributions to high-tech industry applications make her a strong candidate for the “Best Researcher Awards.” Her innovative approach to solving complex problems in polymer science and her successful leadership in key research projects highlight her as an outstanding researcher in her field.

🎓Education:

Dr. Mukti Tyagi completed her B.Sc. in Physics, Chemistry, and Maths from Delhi University. She pursued her M.Sc. in Organic Chemistry from C.C.S.U., Meerut University followed by a Ph.D. in Applied Chemistry from Indraprastha University,  in Delhi Her academic journey laid the foundation for her expertise in polymer chemistry and materials science. During her education, Dr. Mukti Tyagi focused on the synthesis and modification of polymers, particularly for optical applications. She also developed skills in advanced research methodologies, which she later applied to her professional career. Her doctoral research contributed significantly to the understanding of polymer behavior under radiation, and she continues to build on this knowledge in her ongoing work. Through her education, Dr. Mukti Tyagi has established herself as a leading researcher in the field of polymeric materials and their industrial applications.

🏢Work Experience:

Dr. Mukti Tyagi began her career at Shriram Institute for Industrial Research in Delhi, as a Junior Research Fellow. She worked in this position for three years, during which she gained valuable experience in polymer research. Dr. Mukti Tyagi was promoted to Research Fellow, where she advanced her work on polymer synthesis and characterization. Her research led to her promotion to Assistant Scientist B and later to Assistant Scientist A , roles she continues to hold. Throughout her career, Dr. Mukti Tyagi has been involved in various projects related to optical materials, seed coatings, smart materials, and radiation processing. She has played a crucial role in the development of novel materials for industrial applications, particularly in optical plastics and nanocomposites. Dr. Mukti  Tyagi’s experience spans research, product development, and collaboration with industry leaders, making her a key figure in polymer science.

🏅Awards:

Dr. Mukti Tyagi has received numerous accolades for her contributions to polymer science and materials development. Her research on optical polymers and nanocomposites has been widely recognized in the scientific community. She was honored with awards for her innovative work on metal-containing polymers and their applications in optical materials. Dr. Tyagi’s research on dry lubrication systems and shape-memory polymers has garnered attention from key industry stakeholders. She has also received recognition for her involvement in national and international conferences, where she presented groundbreaking research in polymer chemistry and materials science. In addition to her academic recognition, Dr. Tyagi has been awarded several research grants for her work, including support from agencies such as BRNS, DRDO, and Hindustan Thompson Advertising Limited. These awards reflect her ongoing commitment to advancing the field of polymer science and her ability to translate research into practical applications in various industries.

🔬Research Focus:

Dr. Mukti Tyagi’s research focuses on the synthesis, characterization, and modification of polymers for industrial and optical applications. Her expertise includes the development of high refractive index polythiourethane, metal-containing polymers for optical lenses, and nano-dispersed polyacrylates for optical lenses. She has worked extensively on developing advanced materials for the optical industry, including foldable intraocular lenses and tinted contact lenses. Dr. Tyagi is also involved in the creation of smart compositions, such as shape-memory polymers for blast mitigation, and dry lubrication systems for nuclear applications. Her ongoing research includes the synthesis of quaternary ammonium chloride monomers for radiation grafted adsorbents. Dr. Tyagi has made significant contributions to the development of sustainable materials, including natural derivative-based seed coatings and the reduction of fat content in crude casein. Her work aims to bridge the gap between academic research and industrial needs, making her a key figure in applied chemistry and materials science.

Publication Top Notes:

  1.  Novel way of making high refractive index plastics; metal containing polymers for optical applications
    Citations: 100
  2.  Effect of gamma radiation on graphite–PTFE dry lubrication system
    Citations: 12
  3.  Studies on development of polymeric materials using gamma irradiation for contact and intraocular lenses
    Citations: 11
  4. Metal containing polymers for optical applications; part II
    Citations: 6
  5.  Novel nanocomposite optical plastics: dispersion of titanium in polyacrylates
    Citations: 5

 

Prof. Kurosh Rad-Moghadam | Organic Chemistry Award | Best Researcher Award

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Prof. Kurosh Rad-Moghadam | Organic Chemistry Award | Best Researcher Award

Prof. Kurosh Rad-Moghadam, University of Guilan , Iran 

Prof. Kurosh Rad-Moghadam is an esteemed Professor of Organic Chemistry at the University of Guilan, Iran. With a foundation in pure and organic chemistry, he completed his BSc, MSc, and PhD at Shahid Beheshti University, Tehran, focusing on multicomponent syntheses and quinazoline derivatives. Joining the University of Guilan , Prof. Rad-Moghadam has since established himself as a leader in organic synthesis, specializing in advanced NMR spectroscopy, polymer chemistry, and nanotechnology. He has supervised over 60 MSc and PhD theses, guiding pioneering research on bioderived nanocomposites, ionic liquids, and deep eutectic solvents. His innovative contributions include developing sustainable methods in organic synthesis and bio-inspired eutectic melts, contributing significantly to eco-friendly chemical processes. With numerous publications in reputed journals, Prof. Rad-Moghadam continues to advance the frontiers of green chemistry and materials science.

Professional Profile: 

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Summary of Suitability for Award:

Dr. Kurosh Rad-Moghadam demonstrates a remarkable profile of sustained research excellence in organic and pharmaceutical chemistry, which aligns strongly with the criteria for a “Best Researcher Award.” With an h-index of 23 and over 1,500 citations, Dr. Rad-Moghadam’s impact is evident in his innovative research contributions. His pioneering work in organic synthesis, particularly involving bioderived nanocomposites, ionic liquids, and deep eutectic solvents, has advanced sustainable chemistry methods and green solvent alternatives. His published work, represented in high-impact journals, showcases groundbreaking advancements in the synthesis and catalytic applications of ionic liquids, positioning him as a leading researcher in green chemistry.

🎓Education:

Prof. Rad-Moghadam’s academic journey began with a BSc in Pure Chemistry, followed by an MSc and PhD in Organic Chemistry at Shahid Beheshti University, Tehran. His MSc dissertation explored pseudo Mannich-type multicomponent synthesis, a versatile approach in organic chemistry. Building upon this, his PhD research delved into quinazoline derivatives, a class of compounds with pharmaceutical potential. These studies provided him with a robust understanding of organic synthesis principles and innovative approaches to multicomponent reactions. His educational background enabled him to excel in complex areas like bioderived nanocomposites and green chemistry. Through post-graduate studies, he developed expertise in areas pivotal to modern organic chemistry, including advanced NMR spectroscopy and sustainable polymer chemistry, which continue to shape his research endeavors at the University of Guilan.

🏢Work Experience:

With over two decades of teaching and research experience, Prof. Rad-Moghadam has been a central figure at the University of Guilan . He has supervised more than 40 MSc and 20 PhD theses, focusing on bioderived nanocomposites and ionic liquids, with ongoing guidance for 10 PhD and 7 MSc students. His consultancy for a polyurethane adhesive production company exemplifies his engagement in industry-relevant research, particularly in advanced materials. His teaching spans advanced organic synthesis, polymer nanotechnology, and spectroscopy, equipping students with crucial skills for research and industry. His innovative projects have gained international recognition, making him a sought-after researcher in green chemistry. Prof. Rad-Moghadam also actively contributes to scientific communities, furthering the application of eco-friendly chemicals and ionic liquids in organic synthesis.

🏅Awards:

Prof. Rad-Moghadam has received multiple accolades for his pioneering contributions to green chemistry and advanced organic synthesis. Recognized for his innovative work on ionic liquids and bioderived nanocomposites, he has established a reputation as a key figure in sustainable chemistry. His publications in high-impact journals highlight his research’s significance, leading to over 1,500 citations and an h-index of 23, reflecting the impact of his work within the scientific community. He was invited to contribute to the prestigious “Green Solvents II” volume, showcasing his expertise in sustainable solvents and ionic liquids. Prof. Rad-Moghadam’s dedication to education and research excellence has earned him respect as both a mentor and a scientist, positioning him as a leader in advancing green chemistry applications globally.

🔬Research Focus:

Prof. Rad-Moghadam’s research primarily explores eco-friendly synthetic methodologies, focusing on the design and application of bioderived nanocomposites, ionic liquids, and deep eutectic solvents. He has pioneered the use of bio-based materials to enhance the chemical and physical properties of nanoparticles, facilitating advancements in nanotechnology and sustainable materials science. His studies on ionic liquids have introduced novel catalytic properties, opening pathways for energy-efficient synthesis of organic compounds. His development of bioderived eutectic melts with unique thermal properties has potential applications in temperature-sensitive devices and selective synthesis in biosystems. With a strong commitment to green chemistry, his work addresses the environmental impact of traditional chemical processes, promoting renewable resources and reducing chemical waste. His research contributes significantly to sustainable practices in organic synthesis, offering innovative solutions for eco-friendly chemistry.

Publication Top Notes:

  1.  Starch mediates and cements densely magnetite-coating of talc, giving an efficient nano-catalyst for three-component synthesis of imidazo[1,2-c]quinazolines
    Citations: 2
  2.  Deep eutectic melt of betaine and trichloroacetic acid; its anomalous thermal behavior and green promotion effect in selective synthesis of benzimidazoles
    Citations: 1
  3.  A New Bioactive Thiazolidinone-based Azo Dye for Naked-eye Colorimetric Detection of Cyanide Ions
  4. Finely Dispersed Fe3O4 and Ag Nanoparticles Adhered by Starch Nano-layers: an Efficient Catalyst for the Synthesis of Pyrano[2,3-d]Pyrimidines
    Citations: 1
  5.  Ethyl 4-hydroxy-2-oxo-1,2-dihydroquinoline-3-carboxylate in the smiles rearrangement reaction: straightforward synthesis of amino acid derived quinolin-2(1H)-one enamines

 

 

 

 

Evgeny Tretyakov | Organic Chemistry | Best Researcher Award

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Prof Dr. Evgeny Tretyakov| Organic Chemistry | Best Researcher Award

Professor at N. D. Zelinsky Institute of Organic Chemistry, Russia

Prof. Evgeny Tretyakov is a distinguished chemist specializing in organic chemistry and molecular magnetism. Born on March 26, 1968, in Novosibirsk, Russia, he has dedicated his career to advancing the fields of organic radicals, high-spin molecules, and chemical ecology. His contributions to these areas are supported by his extensive research, numerous publications, and leadership roles in both academic and ecological initiatives.

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Prof. Tretyakov has achieved significant recognition in the scientific community. With a total of 3,454 citations across 1,896 documents and an h-index of 29, his research has made a considerable impact in the fields of organic chemistry and molecular magnetism. His high citation count and h-index reflect the influence and relevance of his work in these disciplines.

Education

Prof. Tretyakov’s educational background includes a Master’s Degree in Organic Chemistry from Novosibirsk State University (June 1992). He furthered his studies with a PhD from the Institute of Chemical Kinetics and Combustion, Novosibirsk, in November 1997. His academic journey continued with a Doctor of Science degree in 2009, followed by a professorship at the Institute of Organic Chemistry, Moscow, in July 2009. This solid educational foundation has been crucial in shaping his expertise and research career.

Research Focus

Prof. Tretyakov’s research focuses on organic chemistry and molecular magnetism. His work includes the synthesis of organic radicals and polyradicals, the design of high-spin organic systems, and the creation of magnetically active heterospin complexes. Additionally, he investigates the synthesis of fluorinated heterocycles and quinones. His contributions to chemical ecology include studying persistent organic pollutants and participating in international environmental programs such as the Stockholm Convention and the Arctic Contaminants Action Program.

Professional Journey

Prof. Tretyakov’s professional journey includes key positions in various prestigious institutions. He currently serves as the Deputy Director and Head of the Laboratory of Heterocyclic Compounds at the N. D. Zelinsky Institute of Organic Chemistry. His previous roles include Deputy Director at the Novosibirsk Institute of Organic Chemistry and Head of the Laboratory of Studying Nucleophilic and Radical Ion Reactions. His experience also includes visiting professorships at Max Planck Institute for Polymer Research and Osaka City University, reflecting his international collaboration and influence.

Honors & Awards

Prof. Tretyakov has been recognized with several prestigious awards and honors. These include the State Prize for Young Scientists, awards from the International Science and Education Development Foundation, and the Lavrentiev’s Award of SB RAS. He has also received accolades from the Russian Science Support Foundation and the Presidium SB RAS. These awards highlight his exceptional contributions to scientific research and his leadership in advancing his field.

Publications Noted & Contributions

Prof. Tretyakov has authored and co-authored over 250 scientific publications. Some notable works include studies on the role of paramagnetic ligands in magneto-structural anomalies, light-induced magnetostructural anomalies, and photoswitching in molecular magnets. His research has been published in leading journals such as Inorganic Chemistry, Journal of the American Chemical Society, and Angewandte Chemie, showcasing his significant contributions to the scientific literature.

Synthesis and Photoinduced Behavior of DPP-Anchored Nitronyl Nitroxides: A Multifaceted Approach

  • Journal: RSC Advances
  • Publication Date: 2024
  • DOI: 10.1039/D4RA00916A
  • Contributors: Evgeny Tretyakov, Dmitry Gorbunov, Nina Gritsan, Ashok Keerthi, Martin Baumgarten, Dieter Schollmeyer, Mikhail Ivanov, Anna Sergeeva, Matvey Fedin
  • Summary: This paper explores the synthesis and photoinduced behavior of diphenylphosphine (DPP)-anchored nitronyl nitroxides. The study presents a multifaceted approach to understanding how these compounds behave under light exposure, revealing insights into their photochemical properties and potential applications.

Polyfluorophenyl-Substituted Blatter Radicals: Synthesis and Structure–Property Correlations

  • Journal: Crystal Growth & Design
  • Publication Date: July 3, 2024
  • DOI: 10.1021/acs.cgd.4c00537
  • Contributors: Dmitry Gulyaev, Andrey Serykh, Dmitry Gorbunov, Nina Gritsan, Anna Akyeva, Mikhail Syroeshkin, Galina Romanenko, Evgeny Tretyakov
  • Summary: This article focuses on the synthesis of polyfluorophenyl-substituted Blatter radicals and examines the structure–property relationships of these compounds. The study provides detailed correlations between the molecular structure of the radicals and their physical properties, contributing to the understanding of their behavior and potential uses.

Halogen Bonding as a Supramolecular Modulator of Crystal Packing and Exchange Interactions in Nitronyl Nitroxides

  • Journal: Crystal Growth & Design
  • Publication Date: March 6, 2024
  • DOI: 10.1021/acs.cgd.3c01442
  • Contributors: Pavel V. Petunin, Evgeny V. Tretyakov, Matvey K. Shurikov, Daria E. Votkina, Galina V. Romanenko, Alexey A. Dmitriev, Nina P. Gritsan, Daniil M. Ivanov, Rosa M. Gomila, Antonio Frontera et al.
  • Summary: This research investigates how halogen bonding can modulate crystal packing and exchange interactions in nitronyl nitroxides. The study highlights the role of halogen bonds in influencing the supramolecular organization and magnetic properties of these materials, offering new perspectives on their structural and functional modulation.

A Nitronyl Nitroxide‐Substituted Benzotriazinyl Tetraradical**

  • Journal: Chemistry – A European Journal
  • Publication Date: February 7, 2024
  • DOI: 10.1002/chem.202303456
  • Contributors: Evgeny V. Tretyakov, Igor A. Zayakin, Alexey A. Dmitriev, Matvey V. Fedin, Galina V. Romanenko, Artem S. Bogomyakov, Anna Ya. Akyeva, Mikhail A. Syroeshkin, Naoki Yoshioka, Nina P. Gritsan
  • Summary: This paper reports on the synthesis and properties of a tetraradical compound featuring a nitronyl nitroxide-substituted benzotriazinyl core. The study discusses the electronic structure, magnetic properties, and potential applications of this novel tetraradical, providing insights into its unique behavior and characteristics.

Self-Assembly of Iodoacetylenyl-Substituted Nitronyl Nitroxides via Halogen Bonding

  • Journal: CrystEngComm
  • Publication Date: 2023
  • DOI: 10.1039/D3CE00735A
  • Contributors: Matvey K. Shurikov, Evgeny V. Tretyakov, Pavel V. Petunin, Darya E. Votkina, Galina V. Romanenko, Artem S. Bogomyakov, Sergi Burguera, Antonio Frontera, Vadim Yu. Kukushkin, Pavel S. Postnikov
  • Summary: This article explores the self-assembly of iodoacetylenyl-substituted nitronyl nitroxides through halogen bonding. It presents a detailed analysis of how these interactions influence the formation and organization of molecular assemblies, shedding light on the role of halogen bonding in supramolecular chemistry.

Research Timeline

Prof. Tretyakov’s research timeline spans several decades, with significant contributions starting from his early work in the Institute of Chemical Kinetics and Combustion to his current roles at the N. D. Zelinsky Institute of Organic Chemistry. His research projects have been supported by various grants and fellowships, including those from the Russian Foundation for Basic Research and the Centre National de la Recherche Scientifique. His ongoing research projects focus on areas such as molecular magnets and graphene nanostructures.

Collaborations and Projects

Throughout his career, Prof. Tretyakov has collaborated with leading scientists and institutions worldwide. His projects include the development of switchable molecular magnets, spin-labeled derivatives, and functionalized graphene nanostructures. These projects are supported by various international and national funding bodies, reflecting his strong network and collaborative approach in advancing chemical research.

Strengths of the Best Researcher Award

High Citation Impact: Prof. Tretyakov’s impressive citation metrics (3,454 citations and an h-index of 29) highlight the significant influence and broad recognition of his work in organic chemistry and molecular magnetism.

Diverse Research Focus: His research spans multiple important areas including organic radicals, high-spin molecules, chemical ecology, and molecular magnetism. This diversity showcases his ability to address complex scientific challenges from various perspectives.

Prestigious Publications: Prof. Tretyakov has published extensively in high-impact journals like Inorganic Chemistry, Journal of the American Chemical Society, and Angewandte Chemie. His work on topics such as photoinduced behavior and halogen bonding underscores his contributions to advancing knowledge in his fields.

International Collaboration: His collaborations with esteemed institutions and scientists worldwide (e.g., Max Planck Institute, Osaka City University) reflect his global recognition and the international relevance of his research.

Significant Awards and Honors: The recognition Prof. Tretyakov has received, including the State Prize for Young Scientists and the Lavrentiev’s Award, highlights his outstanding contributions and leadership in scientific research and ecological initiatives.

Areas for Improvement

Broadened Outreach: Although Prof. Tretyakov has made significant contributions to scientific research, increasing outreach through public engagement and science communication could further enhance the visibility and impact of his work outside academic circles.

Interdisciplinary Integration: While his work is diverse, there could be further opportunities to integrate findings from his research on chemical ecology with his studies in molecular magnetism, potentially leading to novel interdisciplinary applications.

Expanded Research Funding: Diversifying the sources and types of funding for his research could provide additional resources and support for exploring new and innovative areas within his field.

Increased Focus on Emerging Trends: Staying ahead of emerging trends in organic chemistry and molecular magnetism, such as advancements in computational methods or new materials, could help maintain his research’s cutting-edge status.

Mentorship and Training: Enhancing efforts in mentoring young scientists and fostering new talent in the field could ensure the continued growth and evolution of research in his areas of expertise.

Conclusion

Prof. Evgeny Tretyakov’s receipt of the Best Researcher Award is a testament to his exceptional contributions to organic chemistry and molecular magnetism. His extensive research, significant publication record, high citation impact, and international collaborations underscore his prominent role in advancing scientific knowledge. While there are areas for potential improvement, such as increasing public outreach and integrating interdisciplinary approaches, his achievements reflect a highly impactful and influential career. Continued focus on emerging trends and mentorship will further enhance his contributions and sustain his position at the forefront of scientific research.