Mariachiara Spennato | Polymer Chemistry | Women Researcher Award

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Dr. Mariachiara Spennato | Polymer Chemistry | Women Researcher Award

Post-doc research fellow| University of Bologna | Italy

Dr. Mariachiara Spennato is an accomplished chemist specializing in sustainable materials and biocatalysis. She earned her PhD in Chemistry from the University of Trieste, where her doctoral research focused on the sustainable valorization of biomass using chemo-enzymatic approaches. Currently, she is a postdoctoral researcher at the University of Bologna, contributing to the H2020 PRESERVE project, which addresses enzymatic recycling and the development of advanced bio-based polymers. Her career reflects a strong commitment to green chemistry, biotechnology, and polymer science, with a clear emphasis on advancing circular bioeconomy solutions. Dr. Spennato has gained international exposure through her Short-Term Scientific Mission under the COST Action, where she applied computational approaches to enzyme characterization. She has authored peer-reviewed publications, engaged in interdisciplinary collaborations, and worked closely with industrial partners. With expertise spanning enzyme immobilization, polymer development, and plastic upcycling, she stands out as a promising young scientist dedicated to sustainable chemical innovation.

Professional Profiles

Dr. Spennato pursued her higher education in Chemistry with dedication and excellence. She completed her PhD in Chemistry at the University of Trieste, where she carried out innovative research on biomass valorization through chemo-enzymatic methods. Her doctoral studies provided her with a strong foundation in biocatalysis, enzyme immobilization, and the application of sustainable technologies in material science. During this period, she focused on integrating biotechnology and chemistry to develop processes that could reduce environmental impact while creating functional, renewable materials. Her training also included exposure to advanced analytical techniques and computational methods, preparing her to tackle complex scientific challenges. The interdisciplinary nature of her PhD research not only enhanced her technical expertise but also strengthened her ability to collaborate across fields such as polymer chemistry, enzymology, and bioengineering. This academic journey laid the groundwork for her current role in cutting-edge European projects centered on sustainable polymers and enzymatic recycling.

Experience 

Dr. Spennato’s professional experience reflects her strong engagement with both academic and applied research. She currently serves as a postdoctoral researcher at the University of Bologna, where she contributes to the H2020 PRESERVE project, focusing on enzymatic recycling and bio-based polymer development. Her prior experience includes participation in several European and national projects such as PRIN CARDIGAN, PRIME, and INTERFACE, which broadened her expertise in biocatalysis and functional material design. Through a COST-funded Short-Term Scientific Mission, she gained valuable international exposure, working on computational enzyme characterization in a collaborative setting. Across these roles, Dr. Spennato has actively published in peer-reviewed journals, fostered collaborations with industry, and applied her skills to practical sustainability challenges. Her experience demonstrates versatility, spanning laboratory-based enzymatic studies, polymer innovation, and computational analysis. She has consistently aligned her work with the principles of green chemistry, advancing solutions for recycling, upcycling, and sustainable material development in line with global needs.

Professional Development

Dr. Spennato has consistently advanced her professional development through active participation in international research collaborations, European projects, and interdisciplinary studies. As part of the H2020 PRESERVE initiative, she works alongside a diverse network of scientists and industrial partners, enhancing her understanding of large-scale, application-oriented research. Her involvement in the COST Action STSM further expanded her competencies in computational enzyme studies, enriching her experimental expertise with modeling approaches. By engaging with projects such as PRIN CARDIGAN, INTERFACE, and PRIME, she has diversified her research scope, moving from biomass valorization and enzyme immobilization to sustainable polymers and circular bioeconomy applications. She continues to strengthen her profile by contributing to publications, attending scientific meetings, and fostering collaborations across institutions like Politehnica University of Timișoara. This ongoing professional development illustrates her commitment to remaining at the forefront of sustainable chemistry, bridging academic research with industrial innovation, and building leadership capacity for future contributions.

Skills & Expertise

Dr. Spennato possesses a multidisciplinary skill set that spans chemistry, biotechnology, and material science. Her expertise lies in biocatalysis, particularly enzyme immobilization for biomass valorization and enzymatic recycling processes. She has developed proficiency in designing bio-based and biodegradable polymers, applying innovative approaches to plastic upcycling and circular bioeconomy solutions. Her research also incorporates supercritical extraction of bioactive compounds and the development of functional materials from renewable resources. Beyond experimental expertise, she has gained skills in computational enzyme characterization, broadening her ability to integrate theoretical and applied approaches. She is adept in handling advanced laboratory techniques, project-based collaborations, and interdisciplinary communication, enabling her to work effectively across academic and industrial environments. Additionally, her experience with European-funded projects has strengthened her project management, grant-writing, and teamwork capabilities. Together, these competencies highlight her as a versatile scientist who can address sustainability challenges through innovation, collaboration, and technical excellence in chemical sciences.

Resarch Focus

Dr. Spennato’s research focus centers on sustainable chemistry, with an emphasis on biocatalysis, polymer science, and circular bioeconomy. She investigates enzymatic processes for biomass valorization, exploring how immobilized enzymes on renewable supports can enhance efficiency and sustainability. A key area of her work is the design and development of bio-based and biodegradable polymers with advanced functionalities, suitable for replacing conventional plastics. Her contributions also include studies on enzymatic recycling and upcycling of synthetic polymers, offering solutions to global plastic waste challenges. Integrating biotechnology with material science, she develops functional materials from renewable resources while applying innovative extraction methods to recover bioactive compounds. She also utilizes computational enzyme characterization to complement her experimental research, enabling a deeper understanding of enzyme mechanisms. Overall, her focus lies in creating environmentally friendly processes and materials that align with the principles of green chemistry, promoting innovation in sustainable materials and polymer circularity.

Awards & Recognitions

Dr. Spennato has been recognized for her scientific achievements through nominations and active participation in prestigious award platforms. Most notably, she has been nominated for the International Chemical Scientist Awards under the category of Women Researchers, which highlights her contributions to sustainability, innovation, and advanced polymer research. Her achievements within European research frameworks, including participation in Horizon 2020 projects like PRESERVE and INTERFACE, as well as national projects such as PRIN CARDIGAN, further underscore her recognition within the scientific community. Her involvement in COST-funded missions also reflects her ability to secure competitive opportunities that advance both her research and professional profile. While still in the early stages of her career, her growing citation record, collaborative publications, and contributions to the field of biocatalysis and polymer sustainability position her as a rising scientist. These recognitions affirm her potential to shape the future of sustainable chemistry through impactful research and innovation.

Publication Top Notes

Dr. Mariachiara Spennato embodies the qualities of an emerging scientific leader and is an excellent candidate for the Women Researcher Award. Her research directly addresses pressing global issues such as plastic waste, bio-based materials, and sustainable processes. With her strong track record of interdisciplinary collaborations and impactful projects, she demonstrates both scientific merit and future leadership potential. Strengthening her international visibility, expanding her citation impact, and taking on leadership roles will further enhance her profile. Overall, she is a deserving nominee whose work reflects the award’s vision of recognizing outstanding women researchers driving innovation and sustainability in chemistry.

Hong Seung Mo | Polymer chemistry | Best Researcher Award

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Dr. Hong Seung Mo | Polymer chemistry | Best Researcher Award

SHINA T&C,  R&D center, South Korea

Dr. Seung-Mo Hong is a highly experienced and innovative R&D professional in the field of polymer engineering, with a dynamic career spanning over two decades. Based in Incheon, South Korea, he holds a Ph.D. in Polymer Engineering from Dankook University, where he explored multifunctional thiol hardeners and their thiol-epoxy curing behavior. He also earned his M.S. and B.S. in Chemical Engineering from Soongsil University. Throughout his distinguished career, Dr. Hong has led groundbreaking research and product development in UV-curable polymers, optical materials, and quantum dot technologies. He has worked with leading organizations like Shin-A T&C, SKC Co., Ltd., and Dongwoo Fine-Chem, spearheading innovations in display materials and adhesives. With over 108 patents and impactful publications, Dr. Hong continues to contribute to advanced material science. His expertise in synthesis, commercialization, and product innovation makes him a driving force in next-generation polymer technologies.

Professional Profile

Education 

Dr. Seung-Mo Hong earned his Ph.D. in Polymer Engineering from Dankook University (2021–2023), where he focused on multifunctional thiol hardeners and thiol-epoxy curing behaviors, graduating with a GPA of 4.37/4.50. Prior to this, he completed his M.S. in Chemical Engineering at Soongsil University (1999–2001) with a thesis on photosensitive polyimides and a GPA of 3.63/4.00. His foundational education was in Chemical Engineering, also at Soongsil University, where he completed his B.S. between 1995 and 1999. Throughout his academic journey, Dr. Hong developed a strong foundation in polymer chemistry, synthesis techniques, and structure-property relationships. His advanced studies focused on both industrial and functional polymers, aligning academic research with practical applications in optical materials and coatings. The rigor and depth of his academic training have equipped him to lead innovation across various industrial R&D platforms and contribute extensively to peer-reviewed scientific literature.

Experience 

Dr. Hong has amassed over 20 years of experience across top-tier R&D institutions and companies. Since 2018, he has led R&D at Shin-A T&C, spearheading innovations in polythiol synthesis, UV inks, and quantum dot optical films. At SKC (2015–2018), he developed multifunctional thiols and high-refractive-index resins for optical lenses. Earlier, he held a pivotal role at Dongwoo Fine-Chem (2006–2015), leading the development of hard coatings, flexible films for OLED, and photosensitive oligomers. His international experience includes a research assignment at Sumitomo Chemical in Japan, where he focused on anti-static and anti-fouling coatings. Beginning his career at SSCP (AkzoNobel) and LG Electronics, Dr. Hong specialized in urethane acrylates and BLU prism sheets. His career reflects deep expertise in polymer synthesis, process scale-up, and product commercialization across diverse applications such as displays, adhesives, and coatings, making him a versatile and strategic leader in the field of advanced materials.

Professional Development

Dr. Seung-Mo Hong has consistently pursued professional development through diverse leadership and technical roles across Korea and Japan. His strengths lie in R&D management, commercialization of high-tech polymer systems, and intellectual property strategy. He is proficient in reverse engineering, defect analysis, VOC resolution, and patent mapping. He has mentored numerous junior researchers and managed large-scale research projects. Notably, his work at Shin-A T&C and SKC led to market-ready innovations in quantum dot resins and multifunctional thiols. Dr. Hong is also fluent in Korean, business-level Japanese, and conversational English, enhancing his collaborative capabilities in multinational settings. He is skilled in using Minitab for statistical analysis and is Six Sigma Green Belt certified. His contributions to the polymer industry are reinforced by 108+ patents and multiple international publications, reflecting his commitment to ongoing innovation and excellence in advanced materials science.

Skills & Expertise

Dr. Seung-Mo Hong possesses a comprehensive skill set centered on advanced polymer science and industrial application. His core competencies include the synthesis and design of UV-curable oligomers and monomers, sulfur-containing compounds, thermoset polymers, and photosensitive materials. He is highly proficient in process development, including commercialization strategies, scale-up procedures, and optimization of production techniques for optical resins and films. Dr. Hong’s material application expertise spans a wide range of products, such as optical films for displays, high-refractive-index lenses, hard coatings, adhesives, and quantum dot-based materials. His analytical capabilities enable him to reverse engineer competitor products, resolve customer complaints, and conduct root cause analysis. Additionally, he is skilled in patent mapping, clearance, and intellectual property risk mitigation. As a seasoned R&D leader, he has mentored junior researchers and led multidisciplinary teams. He is fluent in Korean, professionally proficient in Japanese, and conversational in English, and he is adept at using Minitab and Microsoft Office tools.

Resarch Focus

Dr. Seung-Mo Hong’s research focuses on polymer synthesis, especially UV-curable oligomers and monomers, sulfur-based functional materials, and optical polymers for high-performance applications. His work delves into the development of thiol-based curing systems, high-refractive-index resins, and photosensitive materials for displays and electronics. He has pioneered methods for synthesizing polythiols, epoxy acrylates, and quantum dot UV inks, which have significantly impacted the optical film and display industries. His industrial research encompasses materials for hard coatings, adhesives, lens materials, and flexible electronics, bridging academic precision with commercial applicability. Hong’s approach includes novel chemical formulations, reaction optimization, and product durability improvements. He aligns his research with market trends in displays, wearables, and energy-efficient materials. Through an interdisciplinary lens, Dr. Hong advances polymer technology that underpins next-generation electronic and photonic devices.

Awards & Recognitions

Dr. Seung-Mo Hong’s exceptional contributions to polymer chemistry and industrial innovation have been widely recognized. He received the prestigious Invention King Award from SKC in both 2017 and 2018, honoring his groundbreaking developments in multifunctional thiols and optical materials. While at Dongwoo Fine-Chem, he was honored with the Most Patent Applications Award in 2011, highlighting his prolific output in material innovations, followed by the Excellent Employee Award in 2009. These accolades reflect his ability to transform scientific ideas into commercial products and his dedication to research excellence. In addition to these recognitions, Dr. Hong holds over 100 registered domestic patents and several international patents, demonstrating his continuous impact on the global materials science community. His Six Sigma Green Belt certification further attests to his proficiency in process optimization and quality control, solidifying his reputation as a visionary and highly effective research leader in advanced polymer materials.

Publication Top Notes 

Title: Optimization of synthetic parameters of high purity trifunctional mercaptoesters and their curing behavior for the thiol–epoxy click reaction
Authors: Seung-Mo Hong, Oh Hwan Kim, Seung Hwan Hwang
Year: 2021
Citations: 8+

Title: Synthesis and Characterization of Multifunctional Secondary Thiol Hardeners Using 3‑Mercaptobutanoic Acid and Their Thiol−Epoxy Curing Behavior
Authors: Seung-Mo Hong, Seung Hwan Hwang
Year: 2022
Citations: 10+

Title: Enhancing the shelf life of epoxy monoacrylate resins using acryl phosphate as a reactive additive
Authors: Seung-Mo Hong, Oh Hwan Kim, Seung Hwan Hwang
Year: 2022
Citations: 6+

Title: Synthesis and characteristics of novel 2-hydroxy-3-mercaptopropyl terminated polyoxypropylene glyceryl ether as an epoxy hardener of epoxy-based adhesives
Authors: Seung-Mo Hong, Seung Hwan Hwang
Year: 2022
Citations: 4+

Title: Chemistry of Polythiols and Their Industrial Applications
Authors: Seung-Mo Hong, Oh Hwan Kim, Seung Hwan Hwang
Year: 2024
Citations: 1+

Title: Synthesis of 9,9-bis[4-(2-hydroxyethoxy)phenyl]fluorene di(mercaptopropionate) for high-luminance and refractive prism sheets
Authors: Seung-Mo Hong, Oh Hwan Kim, Seung Hwan Hwang
Year: 2024
Citations: 0 (new)

Title: Synthesis and Characterization of UV-Curable Resin with High Refractive Index for a Luminance-Enhancing Prism Film
Authors: J.H. Song, Seung-Mo Hong, S.K. Park, H.K. Kwon, S.H. Hwang, J.M. Oh, S.M. Koo, G.W. Lee, C.H. Park
Year: 2025
Citations: 0 (new)

Title: Synthesis and characterization of hyperbranched thiol hardener and their curing behavior in thiol–epoxy
Authors: J.H. Song, Seung-Mo Hong, S.K. Park, H.K. Kwon, S.H. Hwang, J.M. Oh, S.M. Koo, G.W. Lee, C.H. Park
Year: 2025
Citations: 0 (new)

Conclusion:

Dr. Hong’s career demonstrates a consistent trajectory of innovation, problem-solving, and technology development in polymer and materials engineering. His cutting-edge research, industrial application success, and outstanding patent portfolio make him a compelling and deserving recipient of the Best Researcher Award. His work not only advances scientific understanding but also significantly contributes to the commercialization of high-performance materials, impacting industries such as display technology, electronics, and optical coatings.

tugba demir caliskan | Polymer chemistry | Best Researcher Award

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Assist. Prof. Dr. tugba demir caliskan | Polymer chemistry | Best Researcher Award

Assistant Professor at Ankara University, Turkey.

🔬 Short Biography 🌿💊📚

Dr. Tugba Demir Caliskan 🌟 is a distinguished researcher in Chemical Engineering at Ankara University 🇹🇷. Her expertise spans the synthesis of polymeric films via PECVD 🧪, development of triboelectric nanogenerators ⚡, and creation of self-healing materials 🩹. She holds a Ph.D. 🎓 in Material Science and Engineering from Clemson University, USA 🇺🇸, where her research focused on oleophobic fluorinated polyester coatings. Previously, she earned her M.S. in Mechanical Engineering and B.S. in Chemical Engineering. Dr. Caliskan has extensive experience in polymer synthesis, surface modification, and the development of advanced composites 🧵. She has worked on DARPA-funded projects 💼, developed antifouling surfaces for medical devices 🏥, and contributed to the advancement of materials for water treatment and energy storage 🌊⚙️. Her interdisciplinary work bridges academic research and industrial applications, driving innovation in smart materials and sustainable technologies 🌍.

PROFILE 

ORCID 

GOOGLE SCHOLAR 

🔍 Summary of Suitability:

Dr. Tugba Demir Caliskan is highly suitable for the Best Researcher Award due to her extensive and impactful research contributions in the fields of polymer science, material engineering, nanotechnology, and surface chemistry. With a solid academic background (Ph.D. from Clemson University, USA) and diverse international postdoctoral experience, Dr. Caliskan has consistently demonstrated innovation, interdisciplinary expertise, and scientific excellence throughout her career.

📘 Education & Experience

Dr. Tugba Demir Caliskan’s academic journey began with a B.S. in Chemical Engineering from Izmir Institute of Technology 🇹🇷. She pursued her M.S. in Mechanical Engineering and Ph.D. in Materials Science and Engineering at Clemson University, USA 🇺🇸. Her doctoral research focused on synthesizing oleophobic fluorinated polyester coatings 🧴. Professionally, Dr. Caliskan gained extensive research experience at Clemson University, developing self-healing polymers 🧪, carbon fibers 🧵, and nanomaterials for sensors 🔬. She later contributed as a postdoc at Bilkent University and Ankara University, enhancing medical device surfaces 🏥, developing water treatment composites 💧, and creating energy storage materials ⚡. In 2024, she was appointed Assistant Professor at Ankara University, continuing her pioneering work in polymer chemistry, nanomaterials, and surface engineering 🌟. Her international experience bridges research, development, and application, positioning her as a leader in advanced material synthesis and characterization 🌍.

Professional Development 🚀📖

Throughout her career, Dr. Caliskan has developed exceptional skills in polymer processing and material characterization 🔬. She is proficient in advanced techniques such as ATRP, PECVD, and controlled radical polymerization 🧪. Her hands-on expertise covers a wide array of instruments including NMR, SEM, TEM, AFM, FTIR, and XRD 📊. Dr. Caliskan excels in managing complex research projects, mentoring students 👩‍🎓, and leading interdisciplinary teams 🧑‍🤝‍🧑. She has also taught numerous university courses in organic chemistry, petroleum technology, and chemical engineering labs 📚. Actively participating in international conferences 🌐, she has presented her work globally, fostering collaborations and advancing her field. Dr. Caliskan’s professional growth is marked by her continuous learning, ability to adapt cutting-edge technologies, and dedication to translating research into practical solutions that address real-world challenges 🌍. Her career exemplifies a perfect blend of academic excellence and industrial relevance 🚀.

Research Focus 🔍🤖

Dr. Caliskan’s research revolves around advanced polymer synthesis and surface engineering 🧪. She specializes in self-healing materials 🩹, triboelectric nanogenerators ⚡, oleophobic and hydrophobic coatings 🌊, and stimuli-responsive polymers 🔄. A significant part of her work focuses on fluorinated polymers for water and oil repellency, creating sustainable alternatives to long-chain perfluoroalkyl substances 🌱. She also develops functional materials for medical devices 🏥, such as antifouling surfaces to prevent biofouling. Her expertise extends to carbon dot composites for water treatment 💧, nanomechanical sensors for gas detection 🧯, and advanced composite materials for aerospace and automotive industries ✈️🚗. By combining polymer chemistry, nanotechnology, and material science, Dr. Caliskan addresses critical challenges in energy storage ⚙️, environmental protection 🌍, and healthcare innovation ❤️‍🩹. Her work is highly interdisciplinary, merging chemistry, engineering, and applied sciences to push the boundaries of smart and functional materials 📈.

Awards and Honors 🏆🎖️

  • 🎓 Awarded Turkish Ministry of Education Scholarship for graduate studies in the USA (2007)

  • 🧪 DARPA-funded research projects on advanced carbon fibers and nanocomposites

  • 🌟 Multiple international conference presentations at ACS and other global events

  • 📖 Numerous peer-reviewed journal publications in top materials science and polymer journals

  • 🏅 Recognition for contributing to pioneering research on self-healing polymers and advanced coatings

Publications & Citations 📚

🔬 Key-and-lock commodity self-healing copolymers — M.W. Urban et al., Science 362 (6411), 220-225 (2018) 📅 — Cited by: 341 📖 🔧
💧 Toward a long-chain perfluoroalkyl replacement: Water and oil repellency of polyethylene terephthalate (PET) films modified with perfluoropolyether-based polyesters — T. Demir et al., ACS Applied Materials & Interfaces 9 (28), 24318-24330 (2017) 📅 — Cited by: 29 📖 🧪
🧴 Highly Oil-Repellent Thermoplastic Boundaries via Surface Delivery of CF3 Groups by Molecular Bottlebrush Additives — L. Wei et al., ACS Applied Materials & Interfaces 12 (34), 38626-38637 (2020) 📅 — Cited by: 25 📖 💡
🧪 Micro-cantilever sensors for monitoring carbon monoxide concentration in fuel cells — T.D. Caliskan et al., Journal of Micromechanics and Microengineering 30 (4), 045005 (2020) 📅 — Cited by: 18 📖 🔬
⚗️ Attainment of water and oil repellency for engineering thermoplastics without long-chain perfluoroalkyls: Perfluoropolyether-based triblock polyester additives — L. Wei et al., Langmuir 34 (43), 12934-12946 (2018) 📅 — Cited by: 14 📖 🌊
🏥 A brief report on managing infected nonunion of a high tibial osteotomy in two stages: a case series involving seven knees — V. Karatosun et al., J Bone & Joint Surgery Br 93 (7), 904-906 (2011) 📅 — Cited by: 13 📖 🦴
🧴 Perfluoropolyether-based oleophobic additives: Influence of molecular weight distribution on wettability of polyethylene terephthalate films — T.D. Caliskan et al., Journal of Fluorine Chemistry 244, 109747 (2021) 📅 — Cited by: 10 📖 💦
🧪 Effect of number of –CF3 groups in tails of polyester on surface wettability of coatings: Synthesis and characterization of PFPE based polyesters with three –CF3 groups in tails — T.D. Caliskan et al., Journal of Polymer Research 27 (5), 128 (2020) 📅 — Cited by: 8 📖 🧬
🌊 Toward the Replacement of Long-Chain Perfluoroalkyl Compounds: Perfluoropolyether-Based Low Surface Energy Grafted Nanocoatings — T. Demir Caliskan et al., ACS Applied Polymer Materials 4 (2), 980-986 (2022) 📅 — Cited by: 7 📖 🔧
🎓 Synthesis and characterization of oleophobic fluorinated polyester films — T. Demir, Clemson University Dissertation (2015) 📅 — Cited by: 4 📖 🎯
🌿 Towards a long-chain perfluoroalkyl replacement: Water and oil repellent perfluoropolyether-based polyurethane oligomers — L. Wei et al., Polymers 13 (7), 1128 (2021) 📅 — Cited by: 3 📖 🧫

🔍 Conclusion:

Dr. Tugba Demir Caliskan exemplifies the qualities of a Best Researcher Award recipient through her continuous pursuit of scientific advancement, cross-disciplinary innovation, and real-world problem-solving. Her research not only advances fundamental science but also delivers practical solutions in healthcare, energy, and environmental sustainability. Her global academic presence, cutting-edge publications, and contributions to both academic and industrial sectors make her an outstanding candidate for this prestigious recognition.

 

 

 

 

 

 

Vedant Joshi | Polymer Chemistry | Best Researcher Award

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Mr. Vedant Joshi | Polymer Chemistry | Best Researcher Award

PhD Scholar of CSIR Indian institute of petroleum mokhampur dehradun in india.

Dr. Elijah W. Stommel 🧠, born in Hamilton, Bermuda 🇧🇲, is a distinguished neurologist and professor at the Geisel School of Medicine at Dartmouth 🏥📚. He holds both an M.D. and Ph.D. from Boston University and has spent decades advancing research in neurology, particularly in Amyotrophic Lateral Sclerosis (ALS) 🧬. Dr. Stommel is widely recognized for his pioneering studies on environmental risk factors and neurodegenerative diseases 🌿🧪. He serves as a staff neurologist at Dartmouth-Hitchcock Medical Center and actively contributes as a reviewer and editor for numerous scientific journals 📖🔬. His dedication to teaching, research, and clinical care continues to inspire. ✨

Professional Profile

🔍 Summary of Suitability:

Vedant Joshi exemplifies the qualities of an outstanding researcher: innovation, technical expertise, and dedication to sustainable scientific advancement 🔬🌱. With over 4 years of focused research experience and a strong academic foundation, he has demonstrated excellence in catalysis, polymer science, and green chemistry. His ongoing PhD at CSIR-IIP reflects a deep commitment to academic and industrial impact 🎓⚗️.

🎓 Education

  • 📘 M.Sc. in Organic Chemistry (2013–2015)
    Government P.G. College, Gopeshwar Chamoli, Uttarakhand, India

  • 📗 B.Sc. (Bachelor of Science) (2011–2013)
    Government P.G. College, Gopeshwar Chamoli, Uttarakhand, India

  • 📚 PhD (Pursuing)
    CSIR–Indian Institute of Petroleum, Dehradun, Uttarakhand

💼 Work Experience

  • 🧪 Project Associate (Oct 2020 – Mar 2023)
    CSIR–Indian Institute of Petroleum, Dehradun

    • Worked on synthesis of Unsaturated Polyester Resin using Parr Reactor

    • Optimized reactant quantities and handled instruments like GPC, Rheometer, Viscometer

  • 🧫 Project Assistant (Feb 2018 – Mar 2020)
    CSIR–Indian Institute of Petroleum, Dehradun

    • Synthesized and optimized noble and non-noble metal catalysts

    • Hands-on work in pilot plant experiments and advanced instrumentation: GC, TEM, TPR-TPD, RAMAN

Professional Development 🚀📖

Vedant Joshi has shown remarkable professional growth through hands-on research and advanced technical skills 🧑‍🔬. He has gained expertise in polymer synthesis, catalyst development, and pilot-scale operations ⚗️. His proficiency with instruments like GC, TEM, Rheometer, and RAMAN 📊 reflects his analytical strength. Vedant actively participated in national and international conferences 🗣️, presenting his research at IIT Guwahati and attending workshops on Transmission Electron Microscopy 🔍. His contributions include multiple peer-reviewed publications and patents 📄💡. Vedant’s commitment to continuous learning and scientific excellence positions him as a valuable asset in sustainable material research and innovation 🌱🔬.

Research Focus 🔍🤖

Vedant Joshi’s research primarily focuses on catalysis, polymer science, and sustainable material development 🔬🌱. His work spans the synthesis and optimization of catalysts, development of unsaturated polyester resins, and advanced functional polymers for environmental and industrial applications ⚗️🧪. He has contributed to green chemistry through innovative methods in desulfurization and bitumen upgrading ♻️🛢️. Vedant is also engaged in nanoarchitectonics for fluorescence sensing of biomolecules like cholesterol and bilirubin 🧫✨. His interdisciplinary approach integrates organic chemistry, material science, and chemical engineering, aiming for eco-friendly and efficient technological solutions for energy and petrochemical industries ⚙️🌍.

🏅 Awards & Honors

  • 🧠 Patent Contributor
    Co-inventor of 3 patents in the fields of reactive desulfurization, novel copolymers, and bitumen additives 🇮🇳📜

    • US Patent: Reactive desulfurization via copolymerization (US 11,802,249 B2)

    • India & US Patent: Novel thiophene-based copolymers (202111061088/0212NF202)

    • India Patent: Additives for bitumen upgradation (202311020225)

  • 🎤 Oral Presentation at SPSI-MACRO 2023
    Delivered a talk at the 17th International Conference on Polymer Science and Technology at IIT Guwahati 🧪🌍

  • 🛠️ Workshop Participation


  • Completed 7-day hands-on training in Transmission Electron Microscopy 🧫🔍

 

Publications & Citations 📚

📘 Fabrication of Au Nanoparticles Supported on One-Dimensional La₂O₃ Nanorods for Selective Esterification of Methacrolein to Methyl Methacrylate – B Paul et al., ACS Sustainable Chem. Eng. 2019, Cited by: 32 🔬

🧪 Low-temperature catalytic oxidation of aniline to azoxybenzene over an Ag/Fe₂O₃ nanoparticle catalyst using H₂O₂ as an oxidant – B Paul et al., New J. Chem. 2019, Cited by: 21 ⚗️

🔷 Development of Highly Efficient and Durable Three-Dimensional Octahedron NiCo₂O₄ Spinel Nanoparticles toward the Selective Oxidation of Styrene – B Paul et al., Ind. Eng. Chem. Res. 2019, Cited by: 19 💎

🔬 Oligomer sensor nanoarchitectonics for “turn-on” fluorescence detection of cholesterol at the nanomolar level – V Joshi et al., Molecules 2022, Cited by: 9 🧬

🔥 Enhanced coke-resistant Co-modified Ni/modified alumina catalyst for the bireforming of methane – S Panda et al., Catal. Sci. Technol. 2023, Cited by: 5 🔥

🌱 An economic, and environmentally benign Psidium guajava L. leaves catalyst for biodiesel production at room temperature – A Sarkar et al., Ind. Crops Prod. 2024, Cited by: 2 🌿

🛢️ Synthesis of polyesters derived from glycerol and phthalic anhydride and its application for bitumen modification – V Joshi et al., J. Appl. Polym. Sci. 2024, Cited by: 2 🧴

🏗️ Use of modified chitosan as bitumen modifier and its impact on rheological properties – K Kumar et al., Environ. Sci. Pollut. Res. 2024, Cited by: 2 🛠️

🧠 Diabetic retinopathy detection using convolutional neural networks – VN Joshi et al., IJRASET 2022, Cited by: 2 👁️

💡 Development of petroleum-derived polymeric additive to enhance bituminous properties with ML model – M Awasthi et al., Sustain. Chem. Environ. 2024, Cited by: – 🤖

📜 Process for preparation of higher-grade VG bitumens using sulfur-based polymeric additives (SBPA) – T Senthilkumar et al., US Patent App. 18/612,469 2024, Cited by: – 🧪

⚙️ Method for reactive desulfurization of crude oil and sulfur rich refinery fractions – A Ray et al., US Patent 11,802,249 2023, Cited by: – 🛢️

🔗 Poly(thiophene-co-benzothiophene-co-dibenzothiophene) copolymers and process thereof – A Ray et al., US Patent App. 18/064,529 2023, Cited by: – 🔬

📖 Mini Review on Conjugated polymer-based Fluorescence Techniques for Bilirubin Detection – V Joshi & T Senthilkumar, BJSTR 2022, Cited by: – 📘

🌊 “Turn-On” Fluorescence Sensing of Bilirubin Using Water-Soluble Conjugated Polymer – TS Kumar et al., Int. J. Anal. Appl. Chem. 2021, Cited by: – 💡

 🔍 Conclusion:

Vedant Joshi’s research blends scientific rigor with real-world relevance. His consistent contributions to sustainability, innovation, and materials science make him a strong and deserving contender for the Best Researcher Award. His work not only advances academic knowledge but also supports industrial applications, aligning with global scientific priorities. 🥇🌐