Mohammad Ansar Vakkattil | Advanced Materials Engineering | Cross-disciplinary Excellence Award

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Mohammad Ansar Vakkattil | Advanced Materials Engineering | Cross-disciplinary Excellence Award

Mr Mohammad Ansar Vakkattil, FHNW, India

Mr. Mohammad Ansar Vakkattil is a dynamic interdisciplinary researcher whose work bridges polymer science, biomedical engineering, and 3D bioprinting. With a solid foundation in Rubber and Polymer Technology from premier Indian institutions like IIT Kharagpur and CUSAT, he has contributed significantly to intelligent materials, medical devices, and bioremediation. His roles as Senior Project Engineer at SCTIMST and researcher at institutions in Switzerland and Estonia reflect his global engagement. His pioneering work on smart materials and 3D-printed implantables, like cranioplasty scaffolds, showcases his innovation at the intersection of healthcare, materials science, and sustainability. With a flair for EU grant writing and multilingual expertise, he embodies the spirit of collaborative, cross-domain research. Through academic supervision, teaching, and publication, Mr. Vakkattil continues to inspire a new generation of material scientists and bioengineers worldwide.

Publication Profile

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Education

Mr. Ansar earned his M.Tech in Rubber Technology from the Rubber Technology Centre, IIT Kharagpur, with a CGPA of 8.02/10, supported by a prestigious GATE scholarship. His thesis focused on castor oil extended epoxidised natural rubber, emphasizing sustainable material innovation. He completed his B.Tech in Polymer Science and Engineering from Cochin University of Science and Technology (CUSAT) with a CGPA of 7.23/10. His academic projects and thesis explored topics such as SBR-tire compounds and mechanical properties of latex films, grounding him in applied polymer engineering. Further technical training at the Indian Rubber Board and multiple industrial internships enriched his hands-on expertise in polymer processing, rubber compounding, and materials testing. His academic journey reflects not only intellectual merit but also a strategic focus on sustainable, biomedical, and smart material innovations.

Experience

Mr. Ansar’s professional experience reflects a blend of academic research and applied engineering. He served as a Senior Project Engineer at Sree Chitra Tirunal Institute for Medical Sciences and Technology, where he contributed to the development of Parylene coatings for implantable medical devices. At the University of Tartu and University of Applied Sciences Northwestern Switzerland, he specialized in 3D printing of artificial muscles and bioprinting for bioremediation. His skills span FDM, SLA, electrospinning, ceramic nanoparticles, and hydrogel synthesis. In addition to his lab work, he has acted as a supervisor, educator, and EU project contributor. His roles demonstrate advanced proficiency in additive manufacturing, smart biomaterials, and digital fabrication—key areas shaping future biomedical and environmental technologies.

Awards and Honors

Mr. Ansar’s academic and professional excellence has been consistently recognized. He was awarded the GATE Masters Scholarship (2016–2018) and achieved an All India Rank of 32 in the GATE Polymer Science and Material Science category. He was the Runner-Up in the Brand D Management Competition during Spring Fest at IIT Kharagpur in 2017. He has also earned accolades for multiple poster presentations, including on biomedical coatings and sustainable rubber materials, at IRMRA and other prestigious platforms. These honors underscore his creativity, technical acumen, and capacity to translate theoretical knowledge into impactful innovations. His teaching merits and development of study materials for GATE aspirants further reflect his commitment to academic excellence and mentorship in polymer sciences.

Research Focus

Mr. Ansar’s research focuses on intelligent materials, additive manufacturing (3D printing), and biomaterials for medical and environmental applications. His work integrates polymer science, smart textiles, hydrogel-based systems, electrospun materials, and bioprinting technologies for creating actuators, biomedical implants, and sustainable filtration systems. Notably, he has investigated bioprinting for bioremediation, parylene coatings for implants, and artificial muscles using FDM and photopolymer techniques. His interdisciplinary approach, combining biopolymer engineering, chemical vapor deposition, and cytocompatibility testing, has led to novel insights in the development of responsive materials and devices. His goal is to bridge the gap between ecological sustainability and human health by advancing customizable, low-impact technologies in the polymer and medical materials domain.

Publication Top Notes

Investigating the Effect of Processing Parameters on Mechanical Behavior of 3D Fused Deposition Modeling Printed Polylactic Acid

Sumana Ghosh (Das) | Chemistry and Materials Science | Best Researcher Award

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Sumana Ghosh (Das) | Chemistry and Materials Science | Best Researcher Award

Dr Sumana Ghosh Das, CSIR-CGCRI, India

Dr. Sumana Ghosh (Das) is a Senior Principal Scientist at CSIR-CGCRI, specializing in bio-ceramics and coatings 🎓🔬. She earned her B.E. from IIEST Shibpur, M.Tech from IIT Kharagpur, and Ph.D. from Jadavpur University. Her groundbreaking research focuses on thermal barrier coatings and microwave processing 📡. With over two decades at CGCRI, she has contributed to numerous high-impact projects and publications 📚. Dr. Ghosh has received prestigious awards like the Bharat Jyoti Award 🏆 and the Lifetime Achievement Award from Marquis Who’s Who 🌍. She actively mentors Ph.D. students and reviews national and international research proposals 👩‍🏫.

Publication Profile

Scopus

Educational Attainments 

Dr. Sumana Ghosh (Das) is a distinguished metallurgical engineer 🔧 with a passion for materials science. She earned her B.E. in Metallurgical Engineering from IIEST, Shibpur in 1998 🎓, followed by an M.Tech. in Materials Science from IIT Kharagpur in 2000 🏗️. In 2010, she completed her Ph.D. at Jadavpur University 🎓, focusing on the structure-property relationship in thermal barrier coatings 🔬. Dr. Ghosh’s academic journey reflects her dedication to advancing material technologies, contributing to innovations in engineering applications. Her expertise bridges the gap between research and practical solutions in the field of metallurgical and materials science.

Professional Experience 

Dr. Sumana Ghosh (Das) is a Senior Principal Scientist at CSIR-CGCRI, Kolkata 🌟. She began her career as a Junior Scientist in 2001 and steadily progressed to Scientist (2006-2011) 🧪, Senior Scientist (2011-2015) 🔬, and Principal Scientist (2015-2020) 🏅. With over two decades of experience, Dr. Ghosh has made significant contributions to the fields of bio-ceramics and coatings 💎. Her expertise continues to drive innovation and advanced research at CSIR-CGCRI, shaping the future of material science in India 🚀.

Scientific Contributions 

Dr. Ghosh is a leading researcher in materials science, with over 14 high-impact publications 📚. Her innovative work explores novel coating methods, microwave sintering, and high-temperature glass-ceramic coatings 🔬. These advancements have paved the way for breakthroughs in aerospace ✈️ and biomedical applications 🏥. Dr. Ghosh’s contributions enhance material durability and performance under extreme conditions, making her a key figure in cutting-edge technology development. Her research bridges fundamental science and real-world applications, driving innovation and expanding the possibilities of modern engineering 🌐.

Research Projects 

She has led and contributed to numerous prestigious projects funded by DRDO, CSIR, ARDB, and DST 🔬💼. Her expertise shines through her leadership in groundbreaking initiatives like microwave processing of ceramic composites ⚙️🔥. This innovative work has paved the way for advancements in high-temperature resistant coatings, crucial for aerospace and defense applications ✈️🛡️. Her dedication to cutting-edge research and collaboration with top scientific organizations highlights her commitment to technological progress and material science excellence 🚀📚. Through these contributions, she continues to drive forward solutions for complex engineering challenges.

Awards and Recognitions 

Dr. Sumana Ghosh (Das) is a distinguished materials scientist 🏅 with numerous accolades. She secured 3rd place 🥉 for Best Poster Paper (2009) by The Indian Ceramic Society & NIIST, CSIR. Honored in Marquis Who’s Who in Science and Engineering 📚 (2011-2020), she received their Lifetime Achievement Award in 2019. A reviewer for NIT Rourkela and CSIR-HRDG, she’s won the Bharat Jyoti Award 🏆, Bharat Excellence Award 🥇, and the Best Citizens of India Award. As an invited speaker globally 🌏, she continues to shape the field of materials science, particularly glass and ceramics.

Leadership and Engagements 

Dr. Ghosh plays a vital role in academic administration 🏛️, serving on Ph.D. selection committees 🎓, project staff recruitment panels 👩‍💻, and internal scientist assessment boards 🧑‍🔬. Her dedication extends to professional societies as a life member of the Indian Ceramic Society 🔬, reflecting her commitment to the field. Dr. Ghosh also contributes to scholarly advancement by regularly reviewing articles for prestigious journals 📚. Her active involvement in these areas highlights her leadership, expertise, and dedication to fostering academic excellence and scientific progress.

Research Focus

Dr. Sumana Ghosh’s research focuses on developing advanced thermal barrier coatings (TBCs) for gas turbine applications 🔥🔧. Her work emphasizes mitigating thermal growth oxidation (TGO) and enhancing high-temperature oxidation and corrosion resistance using novel glass-ceramic and composite materials 🧪🛡️. She explores functionally graded coatings and oxide-based anti-corrosion composites to improve durability and efficiency in harsh environments 🏭💡. Dr. Ghosh’s contributions include studies on microstructure evolution, hot corrosion behavior, and surface protection techniques, paving the way for more resilient and long-lasting turbine components ⚙️✨. Her innovative approaches hold significant potential for advancing materials science and energy systems 🚀.

Publication top notes

Mitigating TGO growth with glass-ceramic based thermal barrier coatings for gas turbine applications

Novel oxide based anti-corrosion composite coating for gas turbines

High-temperature oxidation-resistant glass–ceramic/YSZ composite coatings for gas turbine engine applications

Hot Corrosion Behaviour of Three-Layered Functionally Graded Glass–ceramic–YSZ-based Thermal Barrier Coating System

Surface and interfacial microstructure evolution of isothermally oxidized thermal barrier coating system

Mehdi SALEM | Chemistry and Materials Science | Best Researcher Award

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Mehdi SALEM | Chemistry and Materials Science | Best Researcher Award

Dr Mehdi SALEM, IMT Mines Albi, France

Dr. Mehdi Salem appears to be an excellent candidate for the Best Researcher Award due to his significant contributions in materials science and mechanical engineering, specifically in areas like thermal fatigue, high-temperature corrosion, and additive manufacturing. Below are key factors supporting his suitability:

Publication profile

google scholar

Strong Academic Background

Dr. Salem holds a Doctorate in Mechanical Engineering (2009) from Université Paul Sabatier de Toulouse, with prior degrees in materials science and general engineering. His academic foundation is rooted in prestigious institutions, reflecting his depth in research capabilities.

Professional Experience

With over a decade of experience as a research engineer at Armines – IMT Mines Albi-Carmaux and extensive post-doctoral work, Dr. Salem’s professional career focuses on high-impact research in material fatigue, metal forming processes, and additive manufacturing. His roles as a lecturer further demonstrate his academic leadership.

Expertise and Technical Contributions

His expertise spans advanced topics such as thermal fatigue, corrosion, residual stress evaluation, and additive manufacturing. His technical skills in simulation (e.g., MEF), microstructural analysis, and materials testing position him as a leading researcher in his field.

Publications and Impact

Dr. Salem’s publications, such as his work on thermal fatigue analysis and residual stresses in selective laser melting, have made a significant contribution to mechanical engineering and materials science, with citations demonstrating the relevance of his research. His published papers in top-tier journals like International Journal of Fatigue and Additive Manufacturing have garnered considerable citations, reflecting the impact of his research on both academic and industrial applications.

Multidisciplinary Collaboration

Collaborating with both academic and industrial entities, his research has addressed real-world challenges, such as improving machining quality and enhancing the durability of automotive components. His work on the effect of doum palm fibers and aluminizing on thermal fatigue demonstrates innovative problem-solving in diverse materials.

Research focus

M. Salem’s research primarily focuses on thermal fatigue, additive manufacturing, and composite materials. His work spans analyzing thermal fatigue in automotive diesel pistons and hot work tool steels to improving additive manufacturing processes like selective laser melting and cold metal transfer. He also explores the mechanical and thermal properties of materials, including aluminum alloys and gypsum mortars reinforced with natural fibers. Another key aspect of his research involves developing innovative tools to enhance machining quality and reduce harmful particulate dispersion in composite materials. 🔧🛠️🔥🌡️📊

Conclusion

Dr. Salem’s deep expertise, demonstrated impact through highly cited publications, and his significant technical achievements in thermal fatigue, additive manufacturing, and residual stress analysis make him a standout candidate for the Best Researcher Award. His ongoing contributions to both academic research and industrial applications exemplify his leadership in the field of materials science.

Publication top notes

Thermal fatigue analysis of automotive Diesel piston: Experimental procedure and numerical protocol

Characterisation of 4043 aluminium alloy deposits obtained by wire and arc additive manufacturing using a Cold Metal Transfer process

Improvement of the bridge curvature method to assess residual stresses in selective laser melting

New tool for reduction of harmful particulate dispersion and to improve machining quality when trimming carbon/epoxy composites

The effect of doum palm fibers on the mechanical and thermal properties of gypsum mortar

Effect of aluminizing and oxidation on the thermal fatigue damage of hot work tool steels for high pressure die casting applications

Numerical simulation of thermal fatigue behavior in a cracked disc of AISI H-11 tool steel

A new insight on the analysis of residual stresses related distortions in selective laser melting of Ti-6Al-4V using the improved bridge curvature method

New model for the prediction of the machining depth during milling of 3D woven composite using abrasive waterjet process

Experimental study of thrust force and surface quality when drilling hybrid stacks

 

Kangchun Lee | Chemistry and Materials Science | Best Researcher Award

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Kangchun Lee | Chemistry and Materials Science | Best Researcher Award

Prof Kangchun Lee, KyonggiUniversity, South Korea

Based on the information provided, Prof. Kangchun Lee appears to be a strong candidate for the Best Researcher Award due to his significant achievements and contributions in his field. Here’s a summary of why he stands out.

Publication profile

google scholar

Education and Professional Background

Prof. Kangchun Lee holds a Ph.D. in Energy Engineering from Hanyang University (2020) and a B.S. in Materials Science and Engineering from the same institution (2014). His career began as a Staff Engineer at Samsung Electronics’ Semiconductor R&D Center, where he worked from September 2020 to February 2023. He is currently an Assistant Professor in the Department of Electronic Engineering at Kyonggi University, starting in March 2023. His experience includes comprehensive work on GAA-based semiconductor processes and advanced process development for sub-3nm and sub-2nm semiconductor integration.

Academic and Professional Contributions

Prof. Lee has actively participated in various academic committees and roles, including the International Conference on Planarization/CMP Technology (ICPT) program committee, Korea CMP User Group Meeting (CMPUGM) committee, and as a Topical Advisory Panel Member for Applied Sciences. His involvement in the Early Career Scholars Program and as a Guest Editor for Applied Sciences further highlights his engagement with the academic community.

Awards and Recognition

Prof. Lee has received several prestigious awards, including the Best Paper Award in 2022 from Samsung Electronics and scholarship awards from the Korea Semiconductor Industry Association (2019) and Korea Ceramic Society (2013). These accolades underscore his impactful research and recognition within the industry.

Publications and Research Impact

Prof. Lee’s research has been widely published, with notable contributions to journals such as ECS Journal of Solid State Science and Technology, Materials Science in Semiconductor Processing, and Applied Surface Science. His work covers critical topics such as CMP performance enhancement, advanced CMP slurry compositions, and eco-friendly chemical mechanical planarization techniques. His research is highly cited, reflecting its significance and influence in the field.

Summary

Prof. Kangchun Lee’s educational background, professional experience, active academic involvement, and prestigious awards make him a compelling candidate for the Best Researcher Award. His extensive research output and contributions to semiconductor technology and materials science demonstrate his excellence and impact in his field.

Publication top notes

Tailored electronic structure of Ir in high entropy alloy for highly active and durable bi‐functional electrocatalyst for water splitting under acidic environment

Role of the oxidation state of cerium on the ceria surfaces for silicate adsorption

Fenton-like reaction between copper ions and hydrogen peroxide for high removal rate of tungsten in chemical mechanical planarization

Ce3+-enriched core–shell ceria nanoparticles for silicate adsorption

Highly reversible cycling with Dendrite-Free lithium deposition enabled by robust SEI layer with low charge transfer activation energy

Galvanic corrosion inhibition from aspect of bonding orbital theory in Cu/Ru barrier CMP

Preparation and characterization of slurry for CMP

Synergistic Effect of Mixed Particle Size on W CMP Process: Optimization Using Experimental Design

Optimizing a blend of a mixture slurry in chemical mechanical planarization for advanced semiconductor manufacturing using a posterior preference articulation approach to dual …

Suppression of Dissolution Rate via Coordination Complex in Tungsten Chemical Mechanical Planarization

Weiquan Cai | Chemistry and Materials Science | Best Researcher Award

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Weiquan Cai | Chemistry and Materials Science | Best Researcher Award

Prof Weiquan Cai, School of Chemistry and Chemical Engineering, Guangzhou University, China

Prof. Weiquan Cai: A Leading Contender for the Best Researcher Award.

Publication profile

google scholar

Academic and Professional Background

Prof. Weiquan Cai is a Distinguished Professor and Academic Leader at Guangzhou University, holding this position since 2017. He earned his BS in Chemical Technology from Wuhan Institute of Technology in 1995, an MS in Environmental Engineering from China University of Petroleum in 2002, and a PhD in Chemical Technology from the Institute of Process Engineering, Chinese Academy of Sciences in 2005. His postdoctoral research focused on Material Chemistry and Physics at Wuhan University of Technology, and he was a visiting scholar at Kent State University (2009-2010). In 2012, he joined Wuhan University of Technology as a professor in the School of Chemical Engineering.

Research and Innovations

Prof. Cai has led over 30 research projects funded by various government bodies and enterprises, including five from the National Natural Science Foundation of China and four from Guangdong Provincial Science and Technology Plan. His research includes notable industrial applications, such as a high-efficiency grease cleaning agent. He has published over 200 papers, with around 165 indexed by SCI, including nine Highly Cited Papers. His work has earned significant citations and includes over 115 national invention patents, with 60 granted. His research has led to advancements in materials and chemical engineering, evidenced by his recent publications in prominent journals like Fuel and Chemical Engineering Journal.

Books Published (ISBN)

Prof. Cai co-authored “Chemical Engineering Principles Experiment” (ISBN: 978-7-5629-3466-0), published by Wuhan University of Technology Press in 2011, alongside Guangxu Zhang and Xuanjun Wu.

Patents Published/Under Process

He holds more than 115 national invention patents, with 60 authorized, including one USA invention patent.

Recent Journal Publications

Sorptive-enhanced biogas steam reforming over Pb-modified Ni-CaO bifunctional catalysts (Fuel, 2024). Immobilization of Ni on MOF-derived CeO2 for low-temperature dry reforming of methane (Fuel, 2024). Preparation of poly (vinyl alcohol)/polydopamine/tannin acid coupling of heterogeneous advanced oxidation processes and photocatalysis (Chemical Engineering Journal, 2024).

Publication top notes

Coupling of heterogeneous advanced oxidation processes and photocatalysis in efficient degradation of tetracycline hydrochloride by Fe-based MOFs: Synergistic effect and …

Synthesis of hierarchical Ni (OH) 2 and NiO nanosheets and their adsorption kinetics and isotherms to Congo red in water

Facile synthesis of ordered mesoporous alumina and alumina-supported metal oxides with tailored adsorption and framework properties

Template-free synthesis of hierarchical spindle-like γ-Al 2 O 3 materials and their adsorption affinity towards organic and inorganic pollutants in water

Engineering Bismuth–Tin Interface in Bimetallic Aerogel with a 3D Porous Structure for Highly Selective Electrocatalytic CO2 Reduction to HCOOH

Synthesis of boehmite hollow core/shell and hollow microspheres via sodium tartrate-mediated phase transformation and their enhanced adsorption performance in water treatment

Preparation of amino-functionalized magnetic biochar with excellent adsorption performance for Cr (VI) by a mild one-step hydrothermal method from peanut hull

Rapid degradation of tetracycline hydrochloride by heterogeneous photocatalysis coupling persulfate oxidation with MIL-53 (Fe) under visible light irradiation

Preparation and properties of quaternary ammonium chitosan-g-poly (acrylic acid-co-acrylamide) superabsorbent hydrogels

 

Tamara Erceg | Chemistry and Materials Science | Hypothesis Achievement Award

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Tamara Erceg | Chemistry and Materials Science | Hypothesis Achievement Award

Dr Tamara Erceg, Faculty of Technology Novi Sad, Serbia

Based on Dr. Tamara Erceg’s extensive experience, achievements, and contributions to the field of polymer science, particularly in green chemistry and biodegradable materials, she appears to be a suitable candidate for the Hypothesis Achievement Award. Here are the key points supporting her candidacy.

Publication profile

Orcid

  • Academic Excellence: Dr. Erceg completed her Ph.D. in Polymer Science with the highest average note of 10.00. Her research focuses on the structuring of polymer networks, highlighting her expertise and innovation in the field.
  • Professional Experience: She has been involved in educational and pedagogical work at the Faculty of Technology Novi Sad since 2016, and has been a research associate there, demonstrating her commitment to advancing science and education.
  • Research Contributions: Dr. Erceg has numerous publications in high-impact journals (Q1) covering a wide range of topics, including biodegradable packaging, polymer nanocomposites, and sustainable materials. Her work on active coatings for food packaging and the development of biodegradable cellulose acetate-based films showcases her dedication to solving real-world problems through scientific research.
  • Leadership and Collaboration: She has held significant roles in various projects, including being a project manager for international collaborations and projects funded by the Ministry of Science, Innovation, and Technological Development of the Republic of Serbia. Her involvement in multidisciplinary projects and international conferences highlights her leadership and collaborative skills.
  • Impact and Innovation: Dr. Erceg’s work on biodegradable materials and green chemistry principles aligns with current global priorities on sustainability and environmental protection. Her contributions to the development of eco-friendly packaging solutions and her research on the optimization of biodegradable bags underscore her innovative approach to addressing pressing environmental issues.

  • Research focus

  • Tamara Erceg’s research focuses on the development and characterization of sustainable, eco-friendly materials and active packaging solutions. Her work includes studies on pullulan-based edible coatings to extend cheese shelf life, antioxidant recovery using cloud point extraction, hydrogels, and biodegradable cellulose acetate films. She explores the incorporation of essential oils for antimicrobial packaging and analyzes the thermal stability of bio-based urea-formaldehyde resins. Erceg’s contributions aim to improve food preservation, enhance material properties, and reduce environmental impact through innovative biopolymer applications. 🌿🧀🛡️📦🔬

  • Publication top notes

  • Comparison of the Properties of Pullulan-Based Active Edible Coatings Implemented for Improving Sliced Cheese Shelf Life

  • Updating the Status quo on the Eco-Friendly Approach for Antioxidants Recovered from Plant Matrices Using Cloud Point Extraction

  • Architecture of Hydrogels

  • Hydrolytic and thermal stability of urea-formaldehyde resins based on tannin and betaine bio-fillers

  • Insight on Incorporation of Essential Oils as Antimicrobial Substances in Biopolymer-Based Active Packaging